Recombinant North American type 1 porcine reproductive and respiratory syndrome virus and methods of use

ABSTRACT

Porcine reproductive and respiratory syndrome virus (PRRSV) is a major problem in the pork industry worldwide. The inclusion of markers in vaccines will allow for diagnostic differentiation of vaccinated animals from those naturally infected with wild-type virus. Using a cDNA infectious clone of North American Type 1 PRRSV, a recombinant green fluorescent protein (GFP) tagged PRRSV has been made, containing deletion of an immunogenic epitope, ES4, in the nsp2 region. GFP and ES4 epitope-based ELISAs compliment the marker identification.

This application claims the benefit of U.S. Provisional Application Ser. No. 60/946,080, filed Jun. 25, 2007.

TECHNICAL FIELD

This application relates to the field of molecular virology and more particularly to the construction of recombinant nucleic acids encoding Porcine Reproductive and Respiratory Syndrome Virus (PRRSV).

BACKGROUND

Porcine reproductive and respiratory syndrome (PRRS) is the most economically significant disease of swine worldwide. It is characterized by late term reproductive failure in sows and severe pneumonia in neonatal pigs. The PRRS virus (PRRSV) consists of two major genotypes, European genotype (Type 1) and North American genotype (Type 2), each formerly located on different continents. More recently, Type 1 PRRSV isolates (North American Type 1) have been identified in U.S. swineherds. This group of viruses possesses unique antigenic and genetic characteristics that are distinct from typical North American and European type PRRSV. A unique 51 by deletion has been identified in the immunodominant region of the Nsp2. The etiologic agent of PRRS is a small, enveloped virus containing a single positive-stranded RNA genome. PRRSV belongs to the family Arteriviridae, which includes equine arteritis virus (EAV), lactate dehydrogenase-elevating virus (LDV), and simian hemorrhagic fever virus (SHFV) (Snijder & Meulenberg, 1998). Nucleotide sequence comparisons showed that PRRSV can be divided into distinct European (Type 1) and North American (Type 2) genotypes (Allende et al., 1999; Nelson et al., 1999).

The PRRSV genome is about 15 kb in length and contains nine open reading frames. The 3′ end of the genome encodes four membrane-associated glycoproteins (GP2a, GP3, GP4 and GP5; encoded by sg mRNAs 2-5), two unglycosylated membrane proteins (E and M; encoded by sg mRNAs 2 and 6) and a nucleocapsid protein (N; encoded by sg mRNA 7) (Bautista et al., 1996; Mardassi et al., 1996; Meng et al., 1996; Meulenberg & den Besten, 1996; Meulenberg et al., 1995; Mounir et al., 1995; Wu et al., 2001, 2005). The replicase-associated genes, ORF1a and ORF1b, situated at the 5′ end of the genome, represent nearly 75% of the viral genome. The ORF1ab encoded polyprotein pp1ab is predicted to be cleaved at 12 sites to form 13 products: nsp1α, nsp1β, and nsp2 to nsp12 (Allende et al., 1999; den Boon et al., 1995; Nelsen et al., 1999; Snijder & Meulenberg, 1998).

Modified-live attenuated vaccines against PRRSV are currently available for reduction of clinical disease associated with PRRSV (Boehringer-Ingelheim Animal Health, Inc.). However, they cannot be distinguished serologically between pigs that have recovered from a natural infection and those that have been vaccinated. A genetically marked vaccine would allow the differentiation between vaccinated and naturally infected pigs, which is needed for PRRSV control and eradication programs.

SUMMARY

A recombinant porcine reproductive and respiratory syndrome virus (PRRSV) includes one or more mutations in open reading frame (ORF) 1a, the mutations being such that the recombinant PRRSV fails to produce at least one functional polypeptide corresponding to ORF1a. The mutation may be a deletion. A deletion may be in the nsp2 region, and may include epitope ES4. In one embodiment, the deletion includes amino acids 736-790 of ORF1a. The mutation may include an insertion of a heterologous DNA sequence. An insertion may be between amino acids 733 and 734 of ORF1a. The insertion may include green fluorescent protein (GFP).

A recombinant North American PRRS virus is encoded by an isolated polynucleotide molecule including a DNA sequence encoding an infectious RNA molecule encoding a North American PRRS virus, and the DNA sequence is SEQ ID NO: 43 or a sequence homologous thereto.

A vaccine includes a PRRSV mutant having a mutation in ORF1a, the mutation being such that said PRRSV mutant fails to produce a functional ORF1a polypeptide, and the vaccine includes a pharmaceutically acceptable carrier. The mutation may include a deletion in the nsp2 region, such as a deletion of amino acids 736-790 in the nsp2 region. The mutation may include an insertion of a heterologous DNA sequence. The insertion may be between amino acids 733 and 734 in the nsp2 region.

A kit includes a vaccine including a PRRSV mutant having a mutation in ORF1a, the mutation being such that said PRRSV mutant fails to produce a functional ORF1a polypeptide, the mutation including an insertion of a heterologous DNA sequence, and a pharmaceutically acceptable carrier. The kit further including one or more first polypeptides encoded by the heterologous DNA sequence, and one or more second polypeptides encoded by the functional ORF1a. The mutation in the PRRSV vaccine may be a deletion in the nsp2 region, such as in an ES4 epitope, and the one or more first polypeptides include GFP and the one or more second polypeptides include the ES4 epitope.

A method is provided for differentiating an animal vaccinated with a PRRSV marker vaccine from an animal naturally infected with PRRSV, where the PRRSV marker vaccine includes an insertion mutation and a deletion mutation. The method includes the steps of providing a first recombinant PRRSV protein including the insertion mutation, providing a second recombinant PRRSV protein including the deletion mutation, incubating a serum sample from the animal with the first and second recombinant PRRSV proteins, and detecting binding of antibodies in the sample with the first and second recombinant PRRSV proteins. Binding of antibodies in the sample with the first recombinant PRRSV protein is indicative of a vaccinated animal and binding of antibodies in the sample with the second recombinant PRRSV protein is indicative of a naturally infected animal. The first recombinant PRRSV protein may include a GFP insertion, and the second recombinant PRRSV protein may include an ES4 deletion.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic representation of the PRRSV genome and cloning strategy.

FIGS. 2A-2F depict results of immunofluorescence assays conducted to investigate the infectivity of infectious clone pSD01-08.

FIG. 3 is a graph showing growth kinetics of cloned virus, parental virus, and GFP-expressing virus.

FIG. 4 depicts restriction endonuclease fragment patterns of the RT-PCR products of cloned and parental virus SD01-08.

FIGS. 5A and 5B are graphs showing in vivo characterization of cloned virus.

FIGS. 6A-6C depict the results of immunofluorescence assays conducted to investigate GFP-expressing PRRSV.

FIG. 7 is a schematic representation of the pSD01-08-GFP construct (SEQ ID NOS: 30 and 31).

FIG. 8 is a schematic representation of the pSD01-08-GFP/ΔES4 construct (residues 40-100 and 40-45 of SEQ ID NO: 30).

FIG. 9 is a graph showing growth kinetics of GFP/ΔES4 marker viruses.

FIG. 10 depicts plaque morphology of GFP/ΔES4 marker viruses and parental viruses.

FIG. 11 depicts the stability of GFP expression.

FIG. 12 depicts a comparison of the wild-type GFP gene (SEQ ID NOS: 44-45) to an Arg-97 mutated GFP gene (SEQ ID NOS: 46-47).

FIG. 13 is a graph depicting in vivo characteristics of the GFP/ΔES4 marker virus.

FIGS. 14A-14C are graphs depicting virological and immunological properties of the GFP/ΔES4 marker virus.

FIGS. 15A-15C depict GFP and ES4 epitope-based ELISA results.

DETAILED DESCRIPTION

A full-length cDNA clone, SD01-08, of a North American Type 1 PRRSV isolate was developed. When compared to Lelystad virus, SD01-08 shares 94.1% identity at the nucleotide level (GenBank accession number DQ489311). An important distinction between SD01-08 and LV is the growth properties in PAMs and monkey kidney cells. Results reported by Meulenberg et al (15) showed that wild-type and cloned LV viruses grew well in PAMs, but to low levels in the MA-104 derived cell line, CL2621. Parental and cloned SD01-08 grew equally well on PAMs and MARC-145 cells, another MA-104 derived cell line. The titer of SD01-08 cloned viruses peaked at 48 hpi, while LV cloned viruses grow to lower titers and had not peaked even at 96 hpi. Therefore, the SD01-08 infectious clone replicates well in the continuous cell line. Another difference between LV and SD01-08 is in the level of virulence. In PAMs, the LV cloned virus reached high titers at 10^(7.1) to 10^(7.9) TCID₅₀/ml and peaked around 32 hpi. The SD01-08 cloned virus reached the same titer as its parental virus in PAMs, but their titers were both lower than that of LV, reaching only about 10⁴ TCID₅₀/ml and peaked later, around 72 hpi. This result suggests that SD01-08 cloned virus is less virulent than the LV cloned virus. This conclusion is supported by field observations and an experimental animal challenge study. SD01-08 did not cause significant clinical signs, and only mild pathological lesions observed in the experimental infected pigs. In contrast, LV was reported to cause significant respiratory problems in pigs and abortions in sows (34).

One of the major applications of the infectious clone is to use it as viral backbone for constructing genetically engineered vaccines. Current PRRSV vaccines in the U.S. mainly target the North American Type 2 isolates. The emergence of the North American Type 1 PRRSV requires that vaccines be effective for both genotypes of PRRSV. An essential requirement for any live virus vaccine is that it be low virulence, inducing no or at most very mild disease manifestations. The parental virus, SD01-08 was isolated from a group of pigs showing no clinical signs. Pathogenesis studies confirmed that SD01-08 possesses low virulence properties at the acute phase of the disease, which suggested that the pSD01-08 infectious clone is a potential low virulent strain and suitable for vaccine construction.

One of the key steps in vaccine development is to include markers for the diagnostic differentiation of vaccinated animals from those that are naturally infected with wild-type virus. Marker vaccines are important in programs aimed at controlling or eradicating virus infections in food animals, as well as in companion animals (Babiuk, 1999; Babiuk et al., 1999, 2002; van Oirschot, 2001). Herpesvirus marker vaccines were among the first proved to be effective in the field (Bosch et al., 1996; van Oirschot et al., 1996), followed by various genetically modified RNA viruses, such as classical swine fever virus (Widjojoatmodjo et al., 2000; van Gennip et al., 2002) and Rinderpest virus (Walsh et al., 2000). In EAV eradication programs, since horses are actively involved in international trade and traffic, a marker vaccine is required by some legislative authorities. Discrimination between vaccination and infection is becoming a ruling issue (Castillo-Olivares et al., 2003). Similarly, with a PRRSV elimination program, the international trade in pigs and pork will likely require a marker vaccine in the future. Furthermore, as the world is progressively moving toward elimination of PRRSV, serosurveillance is an essential tool to verify the disease status. The currently available conventional vaccines are unable to allow differentiation between wild-type infection and vaccination. Thus, serosurveillance is impossible in the face of ongoing vaccination or for several months after vaccination has ceased. Clearly, a marked vaccine would be of great benefit.

An infectious clone of North American Type 1 PRRSV, pSD01-08 was used to create a recombinant PRRSV. Compared to a European Lelystad virus (LV) infectious clone, pSD01-08 possesses several distinct biological properties: (1) the pSD01-08 infectious clone was derived from a parental strain isolated in the U.S. in 2001, which represents a North American Type 1 PRRSV; (2) the parental strain SD01-08 was isolated from a group of 8-week-old pigs showing no clinical signs; and (3) SD01-08 possesses a unique 51 by deletion in the immunodominant region of Nsp2 (Fang et al., 2004).

The nsp2 plays a role in the viral replication. The nsp2 contains a cysteine protease domain residing in the N-terminal. This domain induces nsp2/3 cleavage, and also functions as a co-factor with nsp4 serine protease to process the other cleavage products (Snijder et al., 1994, 1995; Wassenaar et al., 1997). Besides its function in viral replication, cysteine proteases of EAV and PRRSV nsp2 have been shown to belong to the ovarian tumor (OTU) protease superfamily. The OTU protease is capable of deconjugating both ubiquitin and ISG15 from cellular proteins, which inhibits Ub- and ISG15-dependent innate immune response (Frias-Staheli et al., 2007).

The development of the marker vaccine is based on the manipulation of cDNA infectious clones, from where a foreign antigen can be inserted (positive marker) or an immunogenic epitope can be deleted (negative marker). The antibody response to the foreign antigen or viral epitope can be used to differentiate vaccinated animals from naturally infected animals. The PRRSV nsp2 is an excellent candidate site for marker modification. The most important property of nsp2 related to marker engineering is the ability of nsp2 to tolerate large deletions and insertions. Nucleotide sequence insertions/deletions have been reported within the central region of the protein (Gao et al., 2004; Shen et al., 2000; Tian et al., 2007; Han et al., 2007). Another property related to marker engineering is the presence of several immunodominant epitopes in this region. Six linear B-cell epitope sites (ES) in the nsp2 region of a Danish Type 1 virus (ES2 to ES7) have been identified (Oleksiewicz et al., 2001). In Type 2 virus, the nsp2 has been found to contain the highest frequency of immunodominant epitopes when compared to structural proteins (de Lima et al., 2006).

Marker modifications in the nsp2 region of a US Type 1 PRRSV infectious clone were prepared. A positive marker, GFP, was inserted into the nsp2 region, but the GFP gene was not stable. Next, a highly immunogenic epitope, ES4, located in the nsp2 region (amino acid 736 to 790 of ORF1a) was deleted and replaced with the GFP gene (at amino acid 733/734 of ORF1a) using reverse genetics, to create a negative marker. The resulting recombinant virus' in vitro replication features and in vivo biological properties were characterized to determine its potential use as marker vaccine against PRRSV infection. The GFP antigen and ES4 peptide antigen-based ELISAs were tested to determine their sensitivity and specificity as companion diagnostic assays for the marker detection and differentiation.

I. Positive Marker GFP

Cells and viruses. A North American Type 1 PRRSV isolate, SD01-08, was originally isolated in 2001 from a group of 8-week-old pigs in the U.S., which were showing no clinical signs of PRRS. Baby hamster kidney cells (BHK-21 C13: American Type Culture Collection) were used for initial transfection for recovery of virus from in vitro transcribed RNA. MARC-145 cells were used for virus rescue and subsequent experiments (Fang et al., 2006). Porcine alveolar macrophages (PAM) cells were obtained by lung lavage of specific-pathogen-free piglets free of PRRSV.

RNA extraction, RT-PCR and sequencing: MARC-145 cells were infected with plaque purified viruses at an MOI of approximately 0.1. After three days, the culture supernatant was layered onto a 0.5 M sucrose cushion and centrifuged at 100,000×g for 14 h in a SW41 rotor (Beckman). RNA was extracted from the pellet using a QIAamp viral RNA kit (Qiagen). To obtain the full-length genome sequence of the parental virus, SD01-08, RT-PCR was performed using a series of primers (Ropp et al., 2004). Each RT-PCR product was directly sequenced at least two times from both directions to obtain the consensus sequences. To construct the infectious clone, nine overlapping fragments (FIG. 1) covering the full-length viral genome flanked by unique restriction enzyme sites were amplified by RT-PCR. The forward and reverse oligonucleotides for the RT-PCR amplification were designed initially based on the sequence of LV (GenBank accession number M96262; 18) and later modified to match SD01-08 sequence (Table 1). RT-PCR was performed (Fang et al., 2004). These RT-PCR amplified fragments were gel purified and cloned in the PCR-Blunt II-Topo vector (Invitrogen). Three clones of each fragment were sequenced and the clone containing the consensus sequence was used for infectious clone assembly.

TABLE 1 Primers used for RT-PCR amplification Genome Position Primers Sequences in SD01-08 Fragment a E4849F 5′ gca tgg ctc tta agg cag 4849-4868 ac SEQ ID NO. 1 E7227R 5′ cag ctt caa ggc agt tgt 7208-7227 ca SEQ ID NO. 2 Fragment b E7139F 5′ tgt tgt gat cgg cgg tat 7139-7158 ta SEQ ID NO. 3 E8297R 5′ cgg cgc ggg cac aca ttt 8271-8297 cgt caa ttt SEQ ID NO. 4 Fragment c E8090F 5′ tac gac cta tcc acc caa 8090-8109 gg SEQ ID NO. 5 E10275R 5′ gaa tct atg gtt atc gca 10254-10275 gag c SEQ ID NO. 6 Fragment d E9946F 5′ cct cga tga ggc tgg ata 9946-9965 tt SEQ ID NO. 7 E12929R 5′ gca cca acc agg agg aaa 12907-12929 aaa gc SEQ ID NO. 8 Fragment e E3173F 5′ cat tct tgc gtc cct caa 3173-3192 at SEQ ID NO. 9 E5352R 5′ cga cag tct ttc tgc cat 5330-5352 caa tg SEQ ID NO. 10 Fragment f E2229F 5′ gct gct gtt gtc ctg tgt 2229-2247 t SEQ ID NO. 11 E3397R 5′ ccg tcg aag ggg gtg gca 3377-3397 tcc SEQ ID NO. 12 Fragment g E12482F 5′ tca ttc gag ctg acc atc 12482-12501 aa SEQ ID NO. 13 E14651R 5′ ctt tat cat tgc acc cag 14631-14651 caa SEQ ID NO. 14 Fragment h E1GF 5′ ggc gcg cct aat acg act  1-16 cac tat aga tga tgt gta ggg tat SEQ ID NO. 15 E2968R 5′ cgc ggg cgc ctg agt tcg 2944-2968 aca aat t SEQ ID NO. 16 Fragment i E14059F 5′ caa cga tcc tac cgc cgc 14059-14080 aca a SEQ ID NO. 17 018 Poly 5′ ggc gat cgg gcg tct agg 15036-15047 AR aat tct aga (T)₄₁ aat ttc ggt cac SEQ ID NO. 18 018 3′ R 5′ ggc gat cgg gcg tct agg After polyA aat tc SEQ ID NO. 19 Unique restriction enzyme site construction in ORF7 E14059F 5′ caa cga tcc tac cgc cgc 14059-14080 aca a SEQ ID NO. 20 YFp503R 5′ ggc ccc agt gct gca atg After polyA ata c SEQ ID NO. 21 Sca1F * 5′ aga aga aaa aga aaa gta 14569-14599 c

g ctc caa tgg g SEQ ID NO. 22 Sca1R * 5′ ccc cat tgg agc 

gt act 14571-14600 ttt ctt ttt ctt SEQ ID NO. 23 GFP insertion in Nsp2 region gfpF 5′ gct cag atg gtg agc aag ggc gag gag c SEQ ID NO. 24 gfpR 5′ gag tct gaa gag gac ttg tac agc tcg tcc a SEQ ID NO. 25 Nsp2F1 5′ tgc tga ctt tct tgc tga 1895-1922 tcc acc tcc t SEQ ID NO. 26 Nsp2R1 5′ cct tgc tca cca tct gag 2408-2420 cac tcc cg SEQ ID NO. 27 Nsp2F2 5′ gct gta caa gtc ctc ttc 2419-2439 aga ctc caa ga SEQ ID NO. 28 Nsp2R2 5′ gcg gac cca gcc agg atc 2732-2753 aga c SEQ ID NO. 29 * The nueleotide mutated for creating Sca1 restriction enzyme site is in bold and italics.

The 5′ and 3′ ends of the genome sequences were determined using a GeneRACER kit (Invitrogen) following the manufacture's instructions. The fragment representing the 5′ terminus of the viral genome was prepared using RT-PCR with primers, E1GF and E2968R (Table 1), which integrates a T7 RNA polymerase site immediately preceding the authentic 5′ terminal nucleotides and an Asc1 restriction enzyme site. The fragment containing the 3′ end sequence was constructed by reverse transcription of RNA with primer 018 polyA, which is flanking the 41 poly A residues and Xbal site. The reverse transcription reaction was followed by PCR with primers E14059F and 018 3′R (Table 1).

Construction of a full-length cDNA clone of a North American Type 1 PRRSV and determination of its infectivity. A full-length genomic cDNA clone of a North American Type 1 PRRSV, pSD01-08 was constructed using the strategy shown in FIG. 1. A low copy number plasmid pACYC177 (GenBank Accession #X06402) was modified by replacing the fragment between the BamH1 and Bgl1 sites with a stuffer fragment, which was prepared as a synthetic gene containing the restriction enzyme sites as shown in FIG. 1. Each of the viral fragments was excised from PCR-Blunt II-Topo using restriction enzymes and ligated into the pACYC177 plasmid, which was digested with the same restriction enzymes. After each ligation step, the pACYC177 construct was transformed into E. coli DH5α cells and grown overnight at 37° C. in the presence of Kanamycin. The completely assembled full-length cDNA clone was sequenced, and the full-length genome sequence was deposited in GenBank under the accession number DQ489311.

To create the Sca1 restriction enzyme site, the silent mutation (G to T mutation) at nucleotide 42 of ORF7 (nucleotide 14588 of SD01-08 genome) was generated using site directed mutagenesis. Site directed mutagenesis was achieved by an overlapping extension PCR technique (Ho et al., 1989; Jespersen et al., 1997) using primer pairs E14059F/Sca1R and Sca1F/YFp503R. The mutated product was confirmed by DNA sequencing analysis.

This construct contains a bacteriophage T7 RNA polymerase promoter at the 5′ terminus of the viral genome, one additional guanosine residue introduced between the T7 promoter and the first nucleotide of the viral genome, the 15047 nucleotides full-length genome of SD 01-08 and a poly (A) tail of 41 residues incorporated at the 3′ end of the genome. Compared to the genome sequence of the parental virus, the DNA sequence of pSD0′-08 contained six nucleotide differences (Table 2).

TABLE 2 Nucleotide differences between the parental SD 01-08 isolate and the full-length cDNA clone. Nucleotide position within SD01-08 Nucleotide in Nucleotide in Amino acid Gene genome parental virus cDNA clone change position 1331 T C Silent Nsp1β 6158 T C Silent Nsp5 8191 A G Silent Nsp9 9492 C T P to L Nsp10 11261 T C Y to H Nsp11 14588 G T Silent ORF7

Four of these differences were silent mutations. The mutation at nucleotide 14588 was introduced to create a unique Sca1 restriction enzyme site into ORF7 for differentiating the cloned virus from parental virus. Two of the nucleotide mutations resulted in amino acid changes, which included the substitution of a C to T at nucleotide 9492 (amino acid P to L) located at Nsp10, and a T to C at nucleotide 11261 (amino acid Y to H) located at Nsp11.

The plasmid pSD01-08 was linearized by restriction enzyme Xbal and used for in vitro transcription by T7 RNA polymerase to synthesize capped RNAs. The in vitro transcribed capped RNA was transfected into BHK-21 cells. At 48 hours post-transfection, cells were examined for the expression of N protein by fluorescent antibody staining with mAb SDOW17 (FIG. 2A). Results in FIG. 2A showed that about 5% of the transfected cells expressed the N protein. Supernatants from the transfected cells were passaged onto MARC-145 cells. After 72 hours, MARC-145 cells were stained using the SD01-08 specific, anti-Nsp2 mAb, ES3-4 58-46 (FIG. 2B), and anti-N mAb SDOW17 (FIG. 2C). A North American Type 2 PRRSV specific, anti-N mAb, MR39 (FIG. 2D), was incorporated as a negative control. The results showed that both Nsp2 and N proteins were detected in MARC-145 cells inoculated with supernatant from the pSD01-08 transfected BHK-21 cells. Upon further passage of the supernatant onto fresh MARC-145 cells (passage 2 on MARC-145 cells), cytopathic effects (CPE) were observed within 48 to 72 hours post infection (hpi). Titration of virus from passage 2 on MARC-145 cells showed an average titer of 3.6×10⁷ FFU/ml. These results indicate that viable and infectious North American Type 1 PRRSV was rescued from the cells transfected with in vitro transcribed RNA.

GFP insertion: The pSD01-08-GFP clone was constructed by inserting the GFP gene sequence (Clontech) into the Nsp2 region (nucleotide 2420/2421) of the viral genome in the plasmid pSD01-08. The GFP gene was amplified from the pEGFP-N1 plasmid (Clontech) with forward primer gfpF and reverse primer gfpR. GFP was inserted by overlapping extension PCR technique (Ho et al.; 1989, Jesperson et al., 1997) using primer pairs of Nsp2F1/Nsp2R1 and Nsp2F2/Nsp2R2. The PCR product was digested with Rsrl1 and Acl1 restriction enzymes and ligated into the pSD01-08 plasmid, which was digested with the same restriction enzymes.

In vitro transcription and rescue of PRRSV: The plasmid, pSD 01-08 or pSD01-08-GFP was linearized with restriction enzyme Xbal. Capped RNA was transcribed with T7 RNA polymerase using the mMessage Machine kit (Ambion) and transfected to BHK-21 cells using DMRIE-C reagent (Invitrogen) following the manufacture's instructions. To rescue the virus, cell culture supernatant obtained 48 hours posttransfection was serially passaged on MARC-145 cells. Rescue of infectious virus was confirmed by indirect immunofluorescent assay (IFA) (Ropp et al., 2004). Monoclonal antibodies (MAbs) were developed for use in the IFA test, including MAb ES3-4 58-46, which specifically recognizes Nsp2 of SD01-08 (Fang et al., Conf. Res. Work. Anim, Dis., abstr. 78, 2004). MAb MR39 specifically recognizes the N protein of the North American Type 2 PRRSV and MAb SDOW17 recognizes the N protein of both genotypes of PRRSV (Nelson et al., 1993; Ropp et al, 2004). For rescue of GFP virus, the expression of GFP was also visualized directly under a fluorescent microscope.

Growth kinetics were examined by infecting MARC-145 cells with cloned virus and parental virus at a MOI of 0.1. Infected cells were collected at 0, 6, 12, 24, 36, 48, 60 and 72 hours post infection, and the virus titers were determined by IFA on MARC-145 cells and quantified as fluorescent focus unit per ml (FFU/ml). Plaque morphology between the cloned virus and parental virus was compared by plaque assay on MARC-145 cells. Confluent cell monolayers were infected with 0.1 MOI of viruses. After 2 hours, cell culture supernatant was removed and an agar overlay was applied. Plaques were detected after five days at 37° C., and stained by using 0.1% crystal violet.

In vitro characterization of cloned virus. The parental virus and cloned virus (passage 2 on MARC-145 cells) were titrated on porcine alveolar macrophages (PAMs). Immunofluorescent staining using anti-N mAb showed that both viruses replicated in PAMs (FIGS. 2E and 2F) and produced the similar virus yield (2.1-2.8×10⁴ FFU/ml) at 72 hpi.

To further compare the growth properties of the cloned and parental viruses, MARC-145 cells were infected with each of the viruses at a MOI of 0.1 and harvested at 6, 12, 24, 36, 48, 60, and 72 hpi. Growth curve results showed that cloned virus possessed similar growth kinetics with that of parental virus (FIG. 3). Titers peaked at 48 hpi for both viruses. The peak titer of the cloned virus was 1.39×10⁷ FFU/ml, versus 2.34×10⁷ FFU/ml for the parental virus. Plaque morphology of these viruses was also determined, the plaque size produced by cloned virus was similar to that of parental virus (data not shown). These results indicate that the cloned virus possesses in vitro properties similar to the parental wild-type virus.

To differentiate cloned virus from the parental virus, we engineered a Sca1 restriction enzyme site at nucleotide 42 of ORF7. As shown in FIG. 4, a 1054 by RT-PCR fragment derived from amplifying the nucleotides 13875 to 14928 was cleaved by Sca1 in the cloned virus. In contrast, the RT-PCR fragment derived from the parental virus was not cleaved by Sca1.

Pathogenic and immunological properties of cloned virus derived from pSD 01-08 in a pig model. An in vivo study of the replication properties of virus derived from the infectious clone using a nursery pig model was performed. Twenty-one 4 week-old, PRRSV naïve pigs from a certified PRRSV-negative herd were obtained and randomly divided into 4 groups housed separately in isolation facilities. After a 4 day acclimation period, pigs from each group (n=6 for cloned virus infected group; n=5 for the remaining groups) were inoculated intranasally with 1 ml 10⁵ TCID₅₀ of cloned virus (group 1) or parental virus (group 2). The third group of animals was inoculated with the current modified live virus (MLV) Ingelvac® PRRSV vaccine. The negative control group (group 4) animals were mock-challenged with MARC-145 cell culture supernatant.

Pigs were observed daily for clinical signs and body temperatures taken for the first 7 days after infection. Blood samples were obtained from all pigs on days 0, 7, 14, 21, 28, 35, and 42. Serum samples were stored at −80° C. for further tests. Two pigs from each group were euthanized at 21 days post inoculation (dpi) for post-mortem analysis of acute infection. The remaining three pigs from each group were euthanized at 42 dpi. Lung lesions of the study animals were evaluated using a previously developed system based on the approximate volume that each lobe contributes to the entire lung: the left and right apical lobes, the left and right cardiac lobes, and the intermediate lobe each contribute 10% of the total lung volume, the left and right caudal lobes each contributes 25%. These scores were then used to calculate the total lung lesion score based on the relative contribution of each lobe (Halbur et al., 1995).

For the detection of viral RNA and determination of viral load, serum samples from 0, 7, 14, 21, 28, 35, and 42 dpi were examined using a real-time, quantitative PCR (Tetracore VetAlert PRRS; Wasilk et al., 2004), which is routinely performed at the South Dakota Animal Disease Research and Diagnostic Laboratory (SDSU-ADRDL). All serum samples were evaluated for anti-PRRSV antibodies using the IDEXX HerdChek® PRRS 2XR ELISA and virus neutralization assay (VN). These tests are also routinely performed at SDSU-ADRDL under strict quality assurance guidelines.

All pigs that received viruses became infected, which was evident by positive RT-PCR results for the presence of viral RNA in serum and by serology. Virus in serum peaked at about 14 days post-infection (dpi) (FIG. 5A; Table 3). At 14 dpi, 5 of 6 pigs in the cloned virus group, 4 of 5 pigs in the parental virus group, and all 5 pigs in the vaccine groups had seroconverted (FIG. 5B; Table 3). Four of the 6 pigs in the cloned virus challenged group had detectable neutralizing antibody titers at 21 dpi, while 1 of the 5 pigs in the parental challenged group developed neutralizing antibodies by 21 dpi. Two of the pigs from the MLV vaccine challenged group developed detectable neutralizing antibody titers at 42 dpi (Table 3).

TABLE 3 Summary of serological and PCR results in serum of inoculated pigs at different days post infection (dpi). Parental virus Cloned virus MLV vaccine dpi PCR^(a) ELISA^(b) VN^(c) PCR^(a) ELISA^(b) VN^(c) PCR^(a) ELISA^(b) VN^(c) 0 0/5 0/5 0/5 0/6 0/6 0/6 0/5 0/5 0/5 7 4/5 1/5 0/5 5/6 0/6 0/6 5/5 0/5 0/5 14  4/5 4/5 0/5 6/6 5/6 0/6 5/5 5/5 0/5 21* 5/5 5/5 1/5 6/6 5/6 4/6 5/5 5/5 0/5 28  2/3 3/3 2/3 4/4 4/4 2/4 3/3 3/3 0/3 35  1/3 3/3 2/3 2/4 4/4 2/4 3/3 3/3 0/3 42  0/3 3/3 3/3 1/4 4/4 2/4 2/3 3/3 2/3 ^(a)PCR: number of pigs with a PCR positive/total number of pigs in each group determined by the real time PCR; ^(b)ELISA: number of seropositive pigs/total number of pigs in each group determined by IDEXX HerdChek ® PRRS 2XR ELISA; ^(c)VN: number of pigs developing neutralizing antibody response/total number of pigs, determined by fluorescent focus neutralization assay. Results interpreted as 90% reduction of the viral infection. *Two pigs euthanized at day 21 for analysis of acute infection.

All mock-infected pigs remained RT-PCR and PRRSV antibody negative throughout the study period. No significant clinical signs were observed in any of the infected pigs. Only mild pathological lung lesions characteristic of PRRSV, such as minor interstitial pneumonia, were observed in 3 of 6 pigs from the cloned virus group, 5 of 5 pigs from the parental virus group and 2 of 5 pigs from the vaccine group. The rest of the pigs did not show gross lung lesions (Table 4). Interestingly, in comparing to the pathological lesions among the pigs from different groups, the lesion scores appear slightly higher in pigs infected with parental virus.

TABLE 4 Percentage of lung with gross pneumonia lesions in infected pigs. Gross lung lesion score (%)* Mock Pig number Cloned virus Parental virus MLV vaccine control #1 0 0.6 0.7 0 #2 1.0 0.5 0 0 #3 0.9 10.5 0 0 #4 0 2.1 0.3 0 #5 0 3.25 0 0 #6 1.5 N/A N/A N/A *Gross lung pathology was assessed by using a gross pig lung lesion scoring system where each lobe of the lung was evaluated for % pneumonia, and the % pneumonia of each lobe was added for entire lung (10).

Introduction of green fluorescent protein into the Nsp2 region of the infectious clone. We explored the potential of using this infectious clone for foreign gene expression. Previous studies showed that Nsp2 is an excellent candidate site for foreign gene insertion. The C-terminal region of Nsp2 for both Type 1 and Type 2 contains hypervariable domains, including amino acid insertions and deletions (7, 8, 27). One of the major differences between the SD01-08 and LV, the prototypic member of European Type 1 viruses, is the presence of a 17 amino acid deletion in the Nsp2, which is located between amino acids 734 to 750 in ORF1 of LV. We inserted a green fluorescent protein (GFP) into this unique deletion site of Nsp2 (at amino acids 733/734 of SD01-08 ORF1a, FIG. 7). The construct, pSD01-08-GFP was in vitro transcribed and transfected into BHK-21 cells. Live cells were examined directly under a fluorescence microscope after 48 hours post-transfection. The cell culture supernatant from transfected BHK cells was passaged onto MARC-145 cells, resulting in the appearance of GFP-expressing cells, which could be clearly visualized as early as 6 hours after infection (FIG. 6A). To confirm the expression of GFP-Nsp2 fusion protein, at 48 hours post-infection, cells were fixed and stained with an Nsp2 specific mAb ES3-4 58-46. ES3-4 58-46 was generated by immunizing mice with synthetic peptide made from ES3 epitope sequence, which is located immediately up-stream of the GFP insertion site (FIG. 7). A red fluorescent Cy3-conjugated goat anti-mouse IgG was used as secondary antibody. Confocal microscopy showed the perinuclear localization of both GFP and Nsp2, similar to Nsp2 localization of the parental virus (FIGS. 6B and 6C). To determine if the expression of GFP affected virus replication, the growth characteristics of the GFP virus were compared to the parental wild-type and cloned viruses. The replication cycle of the pSD01-08-GFP virus was similar to the other viruses, including peak viral titers at 48 hpi; however, the peak titer for the GFP virus infection was approximately 10 fold reduced (FIG. 3).

To investigate the stability of GFP expression over multiple rounds of virus replication, the GFP virus was serially passaged eight times on MARC-145 cells. By the seventh passage, there appeared a subpopulation of non-GFP expressing virus, which was counted as 15% of the total virus population. The loss of GFP was also analyzed by RT-PCR. Total cellular RNA was isolated from cells infected with the seventh passage of the GFP virus, and RNA was used as a template in a RT-PCR reaction with primers that amplified the GFP insertion region. The RT-PCR product was cloned and sequenced. The results revealed that the N-terminal amino acids 1-159 of GFP were deleted (FIG. 7). More interestingly, while the amino acids 1-159 were deleted, two amino acids, methionine (M) and glutamic acid (E) were inserted by the virus before the GFP amino acid 160 (FIG. 7). Therefore, the selection of viral genome encoding the deletion in the GFP gene accounted for the decline in the percentage of infected cells expressing GFP. Taken together, these results indicate that the Nsp2 region can tolerate the introduction of a foreign gene. However, inserting a foreign gene reduces the level of viral replication. The positive marker, GFP gene was thus not stable.

II. Negative Marker Virus GFP/ΔES4

GFP/ΔES4 negative marker vaccine virus construction. In order to obtain a potential negative marker vaccine virus, the B-cell epitope, ES4, that is located downstream of the GFP (at nucleotide 2427 to 2591 of SD01-08 viral genome) was deleted by overlapping extension PCR techniques (Hayashi et al., 1994) using primer pairs ΔES4F/E3448R and E1895F/ΔES4R (Table 5). The PCR product was digested with Rsrl1 and EcoRV restriction enzymes and ligated into the pSD01-08-GFP plasmid, which was digested with the same restriction enzymes. The resulting plasmid construct is designated as pSD01-08-GFP/ΔES4 (FIG. 8).

TABLE 5 Primers used for ES4 epitope deletion and ELISA antigen expression. Genome position Primer name Sequence* in SD01-08^(@) ΔES4F 5′ caa gtc ctc tac agg gcc 2421-2426 cat act c 2592-2606 SEQ ID NO. 32 ΔES4R 5′ ggc cct gta gag gac ttg 2421-2426 tac agc tc 2592-2599 SEQ ID NO. 33 E1895F 5′ ctt gct gat cc acct cct 1905-1926 cag g SEQ ID NO. 34 E3448R 5′ ccg tcg gag ggg gtg gca 3377-3397 tcc SEQ ID NO. 35 Nsp2-2144F 5′ gtc tgt gtc ctt gga cga 2144-2164 gtg SEQ ID NO. 36 Nsp2-2694R 5′ cca agc ggc caa gga tag 2694-2714 atc SEQ ID NO. 37 pET-EGFP-F 5′ cg g gat cc a tgg tga gca — agg gcg agg agc SEQ ID NO. 38 pET-EGFP-R 5′ cct  aag ctt  cct tgt aca — gct cgt cca tgc cg SEQ ID NO. 39 pET-ES4F1 5′ gc  aga tct  tca gac tcc 2427-2444 aag aga gaa SEQ ID NO. 40 pET-ES4F2 5′ gc  aga tct  ggt ggt ggt 2427-2444 ggt tcc tca gac tcc aag aga gaa SEQ ID NO. 41 pET-ES4R 5′ at ccc  aag ctt  gcg g gg 2577-2591 atc c cg gga caa atc ctc g SEQ ID NO. 42 *Nucleotides of GFP are bolded, restriction enzyme sites are italicized and underlined; ^(@)Numbers correspond to nucleotide positions within the SD01-08 genome.

FIG. 8 is a schematic diagram of the pSD01-08-GFP/ΔES4 construct. The GFP was inserted between amino acids 733 and 734 of ORF1a, and the immunogenic B-cell epitope, ES4, located downstream of GFP (at amino acid 736 to 790) was deleted from SD01-08 virus. Direct transfection of this plasmid DNA into BHK-21 cells initiates a full cycle of virus replication. Cell culture supernatants from BHK-21 cells obtained 48 hours post-transfection were passaged onto MARC-145 cells, infectious progeny virus was recovered, and the resulting virus was designated as GFP/ΔES4 marker virus. The parental virus, SD01-08, was generated in parallel from the pSD01-08 cDNA clone. Passage two of the viruses from MARC-154 cells was used for in vitro and in vivo characterization.

Growth kinetics study showed that GFP/ΔES4 marker viruses replicated with slightly slower kinetics, reaching maximal titer several hours later than the parental virus, SD01-08. The peak viral titer of the marker virus (3.34×10⁴ FFU/ml) was approximately two logs lower titer than that of the parental virus (2.56×10⁶ FFU/ml) (FIG. 9). FIG. 9 depicts growth kinetics of GFP/ΔES4 marker viruses. MARC-145 cells were infected in parallel at MOI of 0.1 with the passage three of GFP/ΔES4 marker virus and parental virus. At 0, 6, 12, 24, 36, 48, 60, and 72 hours post infection, cells were harvested and the virus titers were determined by IFA on MARC-145 cells. The results were mean values from three replications of the experiment, and viral titers were expressed as fluorescence focus units per milliliter (FFU/ml). Plaque morphology between the marker virus and parental virus was compared by plaque assay on MARC-145 cells. Viral plaques formed by GFP/ΔES4 marker virus were drastically reduced in size, and most plaques were of pinpoint size (FIG. 10), suggesting a negative effect of the GFP insertion/ES4 deletion on the rate of cell-to-cell spread during infection. FIG. 10 shows plaque morphology of GFP/ΔES4 marker viruses (10-1) and parental viruses (10-2). Confluent cell culture monolayers were infected with viruses at a MOI of 0.1. After 2 hours infection, cell culture supernatant was removed and an agar overlay was applied. Plaques were detected after 5 days at 37° C. and stained by using 0.1% crystal violet.

In vitro stability of the GFP insertion or ES4 deletion in the recombinant viruses was followed for 10 serial passages (72 hours incubation for each passage) in MARC-145 cells. The GFP/ΔES4 region of the virus at passage 10 was sequenced. Surprisingly, unlike the previous SD01-08-GFP virus which experienced a deletion of the N-terminal 159 amino acids, the GFP in the GFP/ΔES4 marker virus remained intact as a full-length gene, and the ES4 deletion was still present. This result indicates that deletion of the ES4 epitope region improved the stability of the inserted foreign gene, GFP. A small population of the infected cells was identified that lost the GFP-associated fluorescence (FIG. 11). GFP expression in MARC-145 cells infected with passage 10 of the GFP/ΔES4 marker viruses is shown in 11-1. The same viral focus stained with AlexiFluor-labeled anti-nucleocapsid monoclonal antibody, SDOW17 (Nelson et al., 1993) is shown in 11-2. The population of viruses that lost GFP fluorescence is shown in the circle.

For the GFP/ΔES4 region, we performed three independent repeats of PCR and sequencing (both forward and reverse directions). Therefore, a total six sequences were obtained. In one of the sequences, a nucleotide C-289 to T-289 mutation was identified, which caused the amino acid mutation of arginine to cysteine at position 97 of the GFP, which may correspond to the small population of infected cells that lost the GFP-associated fluorescence (FIG. 12). No mutation was detected on the other five sequences. FIG. 12 depicts an electrophoregram of the wild-type GFP gene in comparison to the Arg-97 mutated GFP gene. The GFP insertion region was sequenced from cell culture passage 10 of the GFP/ΔES4 marker viruses. Amino acids are presented in a single letter code, and the bold letter indicates mutated amino acid from CGC (Arg) to TGC (Cys).

ES4 and GFP antigens expression. The ES4 antigen was expressed as tandem repeat ES4 epitopes using a modified method described previously (Sun et al., 2004). Briefly, three copies of the ES4 epitope (amino acid 736-790 of ORF1a of SD01-08), were constructed in protein expression vector, pET-28a(+)(Novagen). A flexible peptide linker, GGTGGTGGTGGTTCC (SEQ ID NO: 48), was added between the epitopes to help display the epitopes. There were two forward primers. Forward primer 1, pET-ES4F1 contained BglII restriction site, but without a linker sequence, whereas the forward primer 2, pET-ES4F2 contained not only a BglII restriction site, but also the linker sequence. The ES4 gene fragment was first amplified with the forward primer 1 and reverse primer, pET-ES4R. The PCR product was digested with BglII and HindIII, and then cloned into pET-28a that was digested with BamHI and HindIII. This clone was designated as pET-28a-ES4(+1). The second copy of ES4 was PCR amplified by forward primer 2 and reverse primer, pET-ES4R. The PCR product was digested with BglII and HindIII, and then cloned into pET-28a-ES4(+1) that was digested with BamHI and HindIII. The third copy of the ES4 was inserted using the same strategy as the second copy. The final construct was designated as pET-28a-ES4(+3). The GFP gene was amplified from the pEGFP-N1 plasmid (Clontech) with primer pair pET-EGFP-F/pET-EGFP-R. The PCR product was digested by BamHI and HindIII restriction enzymes and ligated to the pET-28a vector that was digested with the same enzymes. Recombinant proteins were expressed in E. coli BL21 (DE3) to produce a fusion protein with six histidine residues at the N-terminal. The proteins were purified by nickel-affinity chromatography and analyzed by SDS-PAGE as described in our previous publication (Ferrin et al., 2004).

In vivo characterization of GFP/ΔES4 marker virus. The in vivo characteristics of the GFP/ΔES4 marker virus were studied in a nursery pig disease model. Eighteen four-week-old pigs were purchased from a PRRSV-free herd. The animals were randomly separated into three groups (n=6/group) and housed under BL2 isolation conditions with an acclimation period of 7 days before starting experimental inoculations. Group 1 pigs were infected with GFP/ΔES4 marker virus, the group 2 pigs were infected with parental SD01-08 virus as the positive control, and group 3 pigs were mock-infected with the cell culture medium. Group 1 and group 2 pigs were inoculated through both intranasal and intramuscular sites with 1×10⁶ 50% tissue culture infective doses (TCID₅₀) of the virus (1 ml at each site). On 42 days post infection (dpi), group 1 and group 2 pigs were challenged with a heterologous Type 1 strain, SD03-15 virus.

The SD03-15 is another US Type 1 strain, which was isolated from clinical samples submitted to our diagnostic laboratory in 2003. In field reports, pigs infected with SD03-15 were experiencing a pre-weaning mortality of 80-90% for a 3-week period. Decreased performance continued through the finisher phase. In the adult sow population, there was a mild abortion storm, compared to previous US PRRSV outbreaks. Our previous experimental animal study also demonstrated the pathogenic nature of this virus (Lawson et al., Proc. Conf. Res. Work. Anim. Dis., abstr. 99, 2005).

Three pigs from group 3 were challenged with SD03-15 virus, and the other three pigs remained as mock-infected controls. Pigs were observed daily for clinical signs and body temperatures for the first 7 days after infection and the first 7 days after challenge. Mean temperature responses between different challenge groups were compared. Rectal temperatures were taken one day before challenge, and 7 days after challenge. No temperature increase was detected in any pigs after initial infection and no clinical signs were observed. After challenge, rectal temperatures were elevated in those three challenged pigs from Group 3 (initially mock infected) at one and two days post challenge (FIG. 13). Clinical signs (coughing and nasal discharge) were also observed in these three pigs. The rest of the pigs remained asymptomatic. Blood samples were obtained once per week from all pigs. Pigs were euthanized at 21 days post challenge. Gross lung lesions of the study animal were evaluated using a previously developed system based on the approximate volume that each lobe contributes to the entire lung: the left and right apical lobes, the left and right cardiac lobes, and the intermediate lobe each contribute 10% of the total lung volume, and the left and right caudal lobes each contribute 25%. These scores were then used to calculate the total lung lesion score based on the relative contributions of each lobe (Halbur et al., 1995). At necropsy, gross pathologic lesions were not observed in Group 1, Group 2, and the three strict negative control pigs. In contrast, mild gross pathologic lung lesions characteristic of PRRSV were observed in those three pigs from Group 3 that were initially mock infected and then challenged with SD03-15.

Virological and immunological properties. In vivo virological and immunological properties of the marker virus were determined. Pigs were challenged at 42 dpi, shown as a vertical dotted line in FIGS. 14A-14C. The duration and height of viremia was determined by real-time PCR, and the result was interpreted as RNA copy numbers per ml. At each day post-infection, mean viral load with different capital letters (A, B or C) differ significantly (P<0.05). In comparison to Group 2 pigs infected with parental viruses (peak mean viral titer=5.9×10⁷ copies/ml), pigs that were infected with the GFP/ΔES4 marker virus had lower peak viral load (peak mean viral titer=2.08×10⁵ copies/ml, FIG. 14A). At day 7 post-challenge, the viral load was two to three logs lower for the pigs vaccinated than those pigs initially mock infected and then challenged with SD03-15 virus. By day 21 post-challenge, GFP/ΔES4 marker virus infected-group pigs had a 10-fold lower viral load in comparison to the parental group, and 3/5 pigs had eliminated the virus in the serum (FIG. 14A; Table 6).

TABLE 6 Viral load in serum measured by quantitative PCR at 21 days post- challenge with a genetically different strain, SD03-15. Viral load in serum (copies/ml) Negative/ Pig numbers GFP/ΔES4 Parental challenged* Negative 1 0 2.7E+02 N/A 0 2 7.4E+02 0 N/A 0 3 0 1.2E+04 N/A 0 4 N/A 0 3.6E+04 N/A 5 0 2.6E+03 3.3E+04 N/A 6 1.7E+02 1.1E+04 3.6E+04 N/A Mean 1.8E+02 4.3E+03 3.5E+04 0 *Three of the pigs in negative group challenged with the heterologous strain, SD 03-15 at 42 dpi.

By 14 dpi, all of the pigs in infected groups had seroconverted. PRRSV-specific serum antibodies were measured by an IDEXX HerdChek® PRRSV ELISA 2XR kit. S/P ratios of greater than 0.4 are considered positive. The antibody response reached similar levels after 21 dpi (FIG. 14B).

Viral neutralizing antibody response was determined by fluorescent focus neutralization assay (FIG. 14C). Results were interpreted as a 90% reduction of the viral infection, and the neutralizing antibody titers were presented as mean value (n=6) and expressed on a log₂ scale. The parental SD01-08 virus was used for the viral neutralizing assay. At each day post-infection, means with different capital letters (A, B or C) differ significantly (P<0.05). Further measurement of the serum neutralizing (SN) antibody levels showed that in pigs infected with the parental virus, SN antibodies were detected from one of the six pigs by 21 days post-infection, and 3/6 pigs developed detectable SN titer that reached an average geometric mean titer (GMT) of 2 by 35 days post-infection. In contrast, neutralizing antibody responses developed faster and higher in pigs infected with GFP/ΔES4 marker virus. SN antibodies were detected from one of the six pigs by 14 days post-infection, and SN titers were detected from all of the pigs in this group, which reached an average GMT of 9.2 by 35 days post-infection. After challenge with SD03-15, an increased effect was observed, with the GMT of 18.4 from the GFP/ΔES4 marker virus infected group compared to the GMT of 5.7 from the parental virus infected group at 49 dpi (one week after challenge). Both groups reached similar SN titers at 62 dpi (three weeks after challenge) (FIG. 14C). These data suggest that on the initial infection, pigs infected with GFP/ΔES4 marker virus generated higher neutralizing antibody titers than pigs infected with parental virus.

Virus isolation and sequencing. Serum samples from 7, 14, 21, and 28 dpi were used for virus isolation as described previously (Wasilk et al., 2004). The presence of virus was confirmed by IFA with PRRSV specific antibody, SDOW17 (Nelson et al., 1993). To determine the stability of the GFP insertion and ES4 epitope deletion, viral RNA was extracted from the serum-isolated virus using QIAamp Viral RNA mini kit (Qiagen) following the manufacture's instruction. The RT-PCR was performed using previously described methods (Fang et al., 2004). The RT-PCR amplified fragment was gel purified, and the sequence was determined at the Iowa State University sequencing facility (Ames, Iowa). Primer pair nsp2-2144F/nsp2-2694R (Table 5) was used for RT-PCR and sequencing, and amplifies the nucleotide region (2144 to 2694 of SD01-08 genome) containing the GFP insertion and ES4 deletion. The full length sequence of the GFP/ΔES4 marker virus is provided in SEQ ID NO. 43 (Table 7).

In vivo stability of the GFP/ΔES4 marker. To determine stability of the GFP/ΔES4 markers, serum samples from 7 to 28 dpi were used for virus isolation on MARC-145 cells. Viruses were recovered from the serum samples collected on 7, 14, and 21 dpi, and no virus was isolated from the serum samples collected from 28 dpi. In cell culture, we only observed a small population of infected cells showing weak GFP fluorescence with the viruses isolated from 7 and 14 dpi, no GFP fluoresence was observed in infected cells with the viruses isolated from 21 dpi. However, immunofluoresent staining using nucleocapsid protein specific monoclonal antibody, SDOW17 confirmed the presence of a large population of viruses, similar to that observed in the in vitro study (FIG. 11). The stability of the GFP insertion/ΔES4 deletion was determined by sequencing the corresponding regions. The results confirmed the presence of the ES4 deletion, and the GFP remained intact as a full-length gene. However, sequencing results revealed two point mutations that were located at nucleotide 144 (C to T) and nucleotide 289 (C to T) of the GFP. The nucleotide 144 mutation was silent, but the nucleotide 289 mutation caused amino acid mutation of arginine (R) to cysteine (C) at position 97 of the GFP, which is consistent with our in vitro sequencing analysis (FIG. 12). Interestingly, there was still a small population of the non-mutated GFP gene detected in the viruses isolated from 7 and 14 dpi. For each dpi, we have sequenced viruses isolated from three pigs, and sequencing was performed using both forward and reverse primers, resulting in a total of six sequences for each dpi. For the viruses isolated from 7 dpi, 1/6 sequences was found to have no mutation at position 97, and the other five sequences were determined to contain the R to C mutation. For the viruses isolated from 14 dpi, 2/6 sequences identified no mutations, and these two sequences were from two different pigs. The other four sequences were also identified to contain the R to C mutation. All the sequences generated from viruses of 21 dpi contained the R to C mutation. This data was consistent with a previous report (Kim et al., 2007) that the loss of GFP fluorescence is due to the R to C mutation. The presence of small population of the non-mutated GFP would account for the weakly fluorescing cells observed in the cell culture. These results suggest that the selection may have gradually occurred to generate the mutation in favor of improved viral replication.

GFP and ES4 epitope-based ELISA. ELISAs were performed using Immulon II HB 96-well microtiter plates (Thermo Labsystems, Franklin, Mass.). The recombinant protein was diluted in coating buffer (15 mM sodium carbonate-35 mM sodium bicarbonate, pH 9.6), and the plates were coated with 100 ul of the diluted antigen in columns 1, 3, 5, 7, 9, and 11. Columns 2, 4, 6, 8, 10, and 12 were treated with 100 ul of coating buffer as a background control. Plates were incubated at 37° C. for 1 hour, and then excess protein binding sites were blocked with 10% milk in PBST buffer (1×PBS with 0.05% Tween 20) at 4° C. overnight. The test sera were applied at 1:5 dilutions in PBST buffer with 5% milk. After 1 hour incubation at 37° C., plates were washed with PBST and horseradish peroxidase-conjugated goat anti-swine IgG (Kirkegaard & Perry Laboratories, Gaithersburg, Md.) was added to bind to any PRRSV serum antibodies that bound to the antigen on the plates. Plates were incubated at 37° C. for another hour, washed, and the peroxidase substrate ABTS (Kirkegaard & Perry Laboratories, Gaithersburg, Md.) was added for color development. The color development was quantified by reading at 405 nm with an EL800 microplate reader (BioTek Instruments Inc., Winooski, Vt.) controlled by XChek Software (IDEXX Laboratories).

A companion differential diagnostic assay was developed to differentiate animals that were vaccinated with the marker vaccine from those naturally infected with the field viruses. Because two markers, the GFP insertion (positive marker) and ES4 deletion (negative marker), were used, we developed both GFP and ES4 epitope-based ELISA assays for marker detection. Both GFP and ES4 epitopes were expressed as soluble recombinant proteins. We evaluated these two ELISA tests for detecting the specific antibodies. FIG. 15A shows results from the ES4 epitope-based ELISA, and FIG. 15B shows results from the GFP antigen-based ELISA. Pigs were challenged at day 42 post-infection shown as a dotted vertical line in FIG. 15A. As expected, the infection of Group 1 pigs with GFP/ΔES4 marker virus did not induce a detectable antibody response against the deleted ES4 epitope (FIG. 15A), but induced a strong antibody response against the GFP antigen, starting from 14 dpi and continuing for the duration of the study to 62 dpi (FIG. 15B). In contrast, the Group 2 pigs that were infected with parental virus, antibody specific to ES4 recombinant protein could be detected at 21 dpi, and also lasted to 62 dpi (FIG. 15A), while no specific antibody response was detected against GFP antigen (FIG. 15B). After challenged with 03-15, the Group 1 pigs showed a detectable antibody response to the ES4 epitope one week after challenge, since 03-15 virus contains the ES4 epitope (FIG. 15A). No specific antibody response was detected on both GFP and ES4 epitope-based ELISAs for the serum samples from the three strict negative control pigs (FIGS. 15A and 15B).

Serum samples from other Type 1 and Type 2 PRRSV infected animals. A basic requirement for the negative marker is that the antigenic region should be able to react with a broad array of field viruses. To ensure that the ES4 epitope can be reactive in various viral strains, we used serum samples from pigs infected with each of four representative strains of the US Type 1 virus, SD01-07, SD01-08, SD02-11, and SD03-15 (Lawson et al., Proc. Conf. Res. Work. Anim. Dis., abstr. 99, 2005). The SD01-07 and SD01-08 isolates were obtained from herds showing no clinical disease and SD02-11 and SD03-15 were from herds with substantial morbidity and mortality in young pigs. These four isolates also group into different branches of the phylogenetic tree developed for Type 1 PRRSV isolates of US origin (Fang et al., 2007). Serum samples from experimental pigs infected with Type 2 virus, VR2332 were obtained from the shared reagent resource of the PRRSV Cooperative Agriculture Project (CAP). As shown in FIG. 15C, the ES4 epitope reacted with anti-sera from all of the pigs infected with these four viral strains. The results are presented as mean values (n=6). The antibody response was detected by 14 dpi, and lasted more than 62 dpi. However, further testing of serum samples from a group of experimental pigs infected with Type 2 prototypic strain, VR2332 showed no reactivity with the ES4 epitope on the ELISA (data not shown). Therefore, another serological test will be required to differentiate animals infected with Type 1 viruses from those animals infected with Type 2 viruses.

III. Discussion

Two genetic markers in the nsp2 region of the PRRS virus have been constructed. The positive marker (GFP insertion) will allow detection of the animals that have been vaccinated, while the negative marker (ES4 epitope deletion) will allow detecting the presence of wild-type virus in the animals. In comparison to the MLV prepared by traditional multiple cell culture passage techniques, vaccines constructed using this type of precisely defined attenuating deletions/insertions and the use of reverse genetics technology reduces the potential risk of reversion to virulent wild-type viruses.

Marker vaccines are only useful if suitable tests (companion diagnostic tests) are available to monitor the vaccination levels and to follow the spatial course of the infection. The GFP antigen-based ELISA detected a high level of the anti-GFP response in the group of pigs infected with the marker virus. The ES4 epitope-based ELISA also detected a high level of antibody response in the group of pigs infected with the parental virus, but appeared to develop slower than that of the anti-GFP response. A high level, robust anti-GFP response can be detected by 14 dpi in marker virus infected pigs, while anti-ES4 antibody response was detected by 21 dpi and reached higher levels by 28 dpi in pigs infected with wild-type virus. The ES4 epitope possesses the highest hydrophilic values (Hopp & Woods, 1981) among the six B-cell epitopes identified on the nsp2 of Type 1 virus (Oleksiewicz et al., 2001). Analysis of the currently available nsp2 amino acid sequences of Type 1 PRRSV (Meulenberg et al., 1993; Fang et al., 2007) showed that this region possesses 63.6% to 100% amino acid sequence identity within the Type 1 genotype. Protein sequence analysis showed that the ES4 epitope region, AA736-AA790, actually contains seven small B-cell epitopes (PepTool, BioTools, Inc., Edmonton, Alberta, Canada). Epitope AA745-AA754 and AA768 AA780 are well conserved within the Type 1 genotype. Our ES4 ELISA data was consistent with the protein sequence analysis, showing that the ES4 epitope can react with sera samples from animals infected with four representative field strains of Type 1 PRRSV. However, ES4 epitope does not react with serum samples from animals infected with Type 2 isolates. In comparison of the identified B-cell epitopes on nsp2 region (Oleksiewicz et al., 2001; de Lima et al., 2006), none of the epitopes identified in the nsp2 region was conserved between Type 1 and Type 2 isolates. Therefore, another diagnostic assay is required to differentiate pigs vaccinated with the ES4 epitope deletion mutant from those pigs infected with Type 2 field strains.

The ES4 epitope in the nsp2 region appears to be non-essential for PRRSV replication but may play an important role in viral attenuation and pathogenesis in vivo. Insertion of the GFP alone did not substantially reduce the in vitro growth properties of the virus, however, when the ES4 epitope downstream of the GFP was deleted, viral titer was reduced at least two-logs in comparison to that of parental viruses. Plaque morphology also demonstrated negative effects of the markers in virus growth. In vivo characterization further demonstrated that the GFP/ΔES4 marker virus was attenuated with a lower level of viremia and higher level of neutralizing antibody response than that of wild-type virus. Protein sequence analysis has showed that the ES4 epitope region contains the highest hydrophilic value on the nsp2 (Hopp & Woods, 1981).

Surprisingly, the ES4 epitope deletion improved the stability of the GFP insertion in the nsp2. Another interesting observation is the loss of GFP fluorescence in vitro and in vivo although the GFP gene remained intact. Sequence analysis identified the Arg-97 to Cys mutation in the GFP. The Arg-97 to Cys mutation is exactly the same amino acid mutation identified on GFP that was inserted into the nsp2 region of a Type 2 virus (Kim et al., 2007). As indicated by Kim et al (2007) that Arg-97 plays a key role in the chromophore formation of GFP, which suggests that the chromophore formation may affect nsp2 function. In addition, since Cys is the amino acid normally involved in forming the disulfide-bond in the protein, the additional disulfide-bond may be required in maintaining the correct conformation of nsp2 in order to function. Nevertheless, the GFP retains its immunogenicity in vivo, and functions as an excellent positive marker for differentiation between vaccinated and wild-type virus infected animals.

All publications and patent applications in this specification are indicative of the level of ordinary skill in the art to which this invention pertains. All publications and patent applications are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated by reference.

The invention has been described with reference to various embodiments and techniques. However, it should be understood that many variations and modifications may be made while remaining within the spirit and scope of the invention.

TABLE 7 Full length sequence of the GFP/-ES4 marker virus (SEQ ID NO: 43). atgatgtgta gggtatcccc cctacataca caacactttt tgtgtttgtg tactttggag    60 gcgtgggtac agccccgccc caccccttgg cccctgttct agcccaacag gtatccttct   120 ccctcggggc gagtgcgccg cctgctgctc ccttgcagtg ggaaggacct cccgagtatt   180 tccggagagc acctgcttta cgggatctcc accctttaac catgtctggg acgttctccc   240 ggtgcatgtg caccccggct gcccgggtat tttggaacgc cggccaagtc ttttgcacac   300 ggtgtctcag tgcgcggcct cttctctctc cggaacttca ggacactgac ctcggtgtag   360 ttggattgtt ttacaagcct aaggacaaga ttcactggaa agttcctatc ggcattcctc   420 aggtggagtg tactccatcc gggtgctgct ggctctcagc cgtattccct ttggcgcgca   480 tgacttccgg taatcacaac ttcctccaac gacttgttaa ggttgctgat gttttgtatc   540 gcgatggttg cttggcgcct cgacacctcc gtgaactcca agtttacgag cgcggttgta   600 gctggtaccc aattacgggg cccgtacccg gaatgggttt gtttgcgaac tccatgcacg   660 tgtctgacca gccgttccct ggtgccaccc atgtgttgac taactcgcct ctgcctcagc   720 gggcgtgccg gcagccgttc tgtccatttg aggaagctca ttctgacgtt tacaggtgga   780 agaaatttgt gatttttacg gactcctctc ccaacggtcg atttcgcatg atgtggacgc   840 cggaatccga tgactcagcc gccctggagg tgctgccgcc cgagttagaa cgtcaggtcg   900 agatcctcac tcggagtttt cccgctcatc accctatcaa cctagctgac tgggagctca   960 ctgagtcccc tgagaacggt ttttctttcg gcacgtccca ttcttgcggc cacatcgtcc  1020 agaaccccaa cgtgtttgac ggcaagtgct ggctcacctg ctttttgggc caatcggctg  1080 aagtgtgcta ccacgaggaa catctagcta acgccctcgg ttaccaaacc aagtggggcg  1140 tgcatggtaa gtacctccaa cgcaggcttc aagtccgcgg catgcgtgct gtggtcgatc  1200 ctgacggccc tattcacgtt gaagcgctgt cttgctccca gtcttgggtc aggcacctga  1260 ctctgaataa tgatgtcacc ccaggattcg ttcgcctgac atccatccgc attgtgtcca  1320 acacagaacc caccgctttc cggatctttc ggtttggagc acataagtgg tatggcgctg  1380 ccggcaaacg ggctcgtgcc aaacgtgcca ccaaaagtgg gaaggattcg gccctcgctc  1440 ccaagattgc cccaccggtc cccacctgtg gaatcaccac ctactctcca ccgacagacg  1500 ggtcttgtgg ttggcacgtt cttgccgcca tagtgaatcg gatgataaac ggtgacttta  1560 cgtcccccct gcctcagtac aacagaccag aggatgattg ggcttctgat tatgatcttg  1620 ctcaggcgat tcaatgttta caactgcctg ccaccgtggt tcggaatcgc gcctgtccta  1680 acgccaagta cctcataaag ctaaacgggg ttcactggga agtagaggtg agatctggaa  1740 tggctcctcg ttccctttct cgtgaatgtg tagttggcgt ttgctctgaa ggctgtgtcg  1800 caccgcctta tccagcggac gggcttccta aacgtgcact cgaggccttg gcgtctgcct  1860 acagactacc ctcagattgt gttagctctg gtattgctga ctttcttgct gatccacctc  1920 ctcaggaatt ctggactctc gacaaaatgt tgacctcccc gtcaccggag cggtccggct  1980 tctccagctt gtataaatta ctcttagagg ttgttccgca aaaatgtggt gctacggaag  2040 gggctttcgt ctatgctgtt gagaggatgt taaaggactg tccgagcccc gaacaggcca  2100 tggcccttct ggcaaaaatt aaagttccat cctcaaaggc cccgtctgtg tccttggacg  2160 agtgttttcc tgcgggtgtt ccagccgact tcgagccagc atttcaggaa aggccccaaa  2220 gtcccggtgc tgctgtcgcc ctgtgttcac cggacgcaaa agggttcgag ggaacagcct  2280 cggaagaagc tcaagagagt ggccataagg ccgtccacgc tgtacccctt gccgaaggtc  2340 ccaataatga acaggtacag gtggttgctg gtgagcagct agagctcggc ggttgtggtt  2400 tggcaatcgg gagtgctcag atggtgagca agggcgagga gctgttcacc ggggtggtgc  2460 ccatcctggt cgagctggac ggcgacgtaa acggccacaa gttcagcgtg tccggcgagg  2520 gcgagggcga tgccacctac ggcaagctga ccctgaagtt catctgcacc accggcaagc  2580 tgcccgtgcc ctggcccacc ctcgtgacca ccctgaccta cggcgtgcag tgcttcagcc  2640 gctaccccga ccacatgaag cagcacgact tcttcaagtc cgccatgccc gaaggctacg  2700 tccaggagcg caccatcttc ttcaaggacg acggcaacta caagacccgc gccgaggtga  2760 agttcgaggg cgacaccctg gtgaaccgca tcgagctgaa gggcatcgac ttcaaggagg  2820 acggcaacat cctggggcac aagctggagt acaactacaa cagccacaac gtctatatca  2880 tggccgacaa gcagaagaac ggcatcaagg tgaacttcaa gatccgccac aacatcgagg  2940 acggcagcgt gcagctcgcc gaccactacc agcagaacac ccccatcggc gacggccccg  3000 tgctgctgcc cgacaaccac tacctgagca cccagtccgc cctgagcaaa gaccccaacg  3060 agaagcgcga tcacatggtc ctgctggagt tcgtgaccgc cgccgggatc actctcggca  3120 tggacgagct gtacaagtcc tctacagggc ccatactccg tcatgttgag cactgcggca  3180 cagagtcagg cgacagcagt tcgcctttgg atctgtcttt tgcgcaaacg ttggaccagc  3240 ctttagatct atccttggcc gcttggccgg tgaaggccac cgcgtctgat cctggctggg  3300 tccgcggtag gtgcgagcct gtctttttaa agcctcggaa agctttctct gatggcgatt  3360 cggcccttca gttcggggag ctttctgagt ccagctctgt catcgagttt gaccagacaa  3420 aagatactct ggtggctgac gcccctgttg acttgacgac ttcgaacgag gccctctctg  3480 cagtcgaccc ttccgaattt gtcgaactca ggcgcccgcg tcattccgca caagccttaa  3540 ttgaccgagg cggtccactt gctgatgtcc atgcgaaaat aaagaaccgg gtgtatgaac  3600 agtgcctcca agcttgtgag cctggtagtc gtgcaacccc agccaccagg gagtggctcg  3660 acaaaatgtg ggatagggtg gacatgaaaa cttggcgctg cacttcacag ttccaggccg  3720 gtcgcattct tgcgtccctc aaatttcttc ctgacatgat tcaagacacg ccgcctcctg  3780 tccccaagaa gaaccgagct agtgacagtg ccggtcagac cgtccctccg cctacggata  3840 tccagcaaga ggatgccacc ccctccgacg ggttatccca tgcatcggat ttttctagtc  3900 gagtgagcac gagctggagt tggaaaggcc ttatgctttc cggcacccgt ctcgcggggt  3960 ctgctggtca gcgcctcatg acatgggttt ttgaagttta ctcccatctc ccagctttta  4020 tactcacact tttctcgccg cggggctcta tggctccagg cgattggttg tttgcaggtg  4080 ttgttttact tgctctcttg ctctgtcgtt cttacccaat actcggatgc cttcccttac  4140 tgggtgtctt ctctggttct ttgcggcgtg ttcgtctggg tgtttttggt tcttggatgg  4200 cttttgctgt atttttattc tcgactccat ccaacccagt cggttcttct tgtgaccacg  4260 attcgccgga atgtcatgct gagcttttgg ctcttgagca gcgccaactt tgggaacctg  4320 tgcgcggcct tgtggttggc ccctcaggtc tcttatgtgt catccttggc aagttactcg  4380 gtgggtcacg tcatctctgg catgttatcc tacgtttatg catgcttaca gatttggccc  4440 tttctcttgt ttatgtggtg tcccaagggc gttgtcacaa gtgttgggga aagtgtataa  4500 ggacagctcc tgctgaggtg gctctcaatg tatttccttt ctcgcgcgcc actcgcaact  4560 ctctcacatc cttgtgtgat cggttccaaa ctcctaaagg agttgatccc gtgcacttgg  4620 caacgggttg gcgcgggtgt tggcgtggtg agagtcccat ccatcaacca caccaaaagc  4680 ccatagctta tgccaatttg gatgaaaaga aaatatctgc tcaaacggtg gttgctgtcc  4740 catacgaccc cagtcaggct atcaaatgtc tgaaggttct gcaggcggga ggggctatcg  4800 tggaccagcc tacgcctgaa gttgttcgtg tgtctgaaat ccccttttca gccccatttt  4860 tcccaaaagt tccagtcaac ccagattgca ggattgtggt ggattcagat acttttgtgg  4920 ctgcagtccg ctgcggttac tcgacagcac aactggtcct aggccggggc aactttgcca  4980 agttgaatca gacccccctt agggactctg cctccaccaa aacgactggt ggggcctctt  5040 atactcttgc tgtggctcaa gtgtctgtgt ggactcttgt tcatttcatc ctcggtcttt  5100 ggttcacatc acctcaagtg tgtggccgag gaaccgctga cccatggtgt tcaaatccct  5160 tttcgtatcc tgcctacggc cctggagttg tgtgctcctc tcgactttgt gtgtctgccg  5220 atggggtcac cctgccattg ttctcagctg tggcacaact ctccggtaga gaggtaggga  5280 tttttatttt agtgcttgtt tccttgactg ccttggccca tcgcctggct cttaaggcag  5340 acatgttagt ggtcttttca gctttttgtg cttacgcctg gcccatgagc tcctggttaa  5400 tctgcttctt tcctatactc ttaaagtggg ttacccttca ccccctcact atgctttggg  5460 tgcactcatt cttggtgttt tgtatgccag cagccggcat cctctcacta gggataactg  5520 gccttctctg ggcagttggc cgctttaccc aggttgccgg aattattaca ccttatgaca  5580 tccaccagta tacctctggg ccacgcggtg cagccgctgt agccacagcc ccagaaggca  5640 cttatatggc cgccgtccgg agagctgctt taactggacg aactttgatc ttcaccccgt  5700 ctgcggtcgg atcccttctt gaaggtgctt tcaggactca taaaccctgc cttaacaccg  5760 tgaatgttgt gggttcttcc cttggttctg gaggggtttt taccattgat ggcagaaaga  5820 ccgtcgtcac tgctgctcat gtgttgaacg gcgacacagc tagagttacc ggcgactctt  5880 acaaccgcat gcacactttt aagaccagtg gcgattatgc ctggtcccat gctgatgact  5940 ggcagggcgt tgcccctgtg gtcaaggttg cgaaggggta tcgcggtcgt gcctactggc  6000 aaacatcaac cggtgtcgaa cccggcgtca ttggggaagg gttcgccttc tgtttcacca  6060 actgtggcga ttcggggtca cccgtcatct cagaatctgg tgatctcatc ggaatccata  6120 ccggttcaaa caaactcggt tctggtcttg tgacgacccc tgaaggggaa acctgcgcca  6180 tcaaagaaac caagctctct gaccttccca gacattttgc gggcccgagc gtccctcttg  6240 gggacattaa attgagtccg gccatcgtcc ctgatgtaac atctattccg agtgacttgg  6300 ctacgctcct agcttccgtc cctgtaatgg aaggcggcct ctcgaccgtt caacttctgt  6360 gtgtcttttt ccttctctgg cgcatgatgg gccatgcctg gacacccatt gttgccgtgg  6420 gcttcttttt gctgaatgaa attcttccag cagttttggt ccgagccgtg ttttcctttg  6480 cactctttat tcttgcatgg gccaccccct ggtccgcaca ggtgttaatg attagactcc  6540 tcacggcatc cctcaaccgc aacaagttgt ctctggcgtt ctacgcactt gggggtgtcg  6600 tcggtttggc cgctgaaatc ggggcttttg ccggcaggct gcctgaattg tctcaagctc  6660 tttcgacata ctgtttctta cctagggtcc ttgccatggc cagttatgtt cccatcatca  6720 tcattggtgg actccatgcc ctcggtgtga ttctgtggtt gttcaaatac cggtgcctcc  6780 acaactagct ggttggtgat gggagtttct caagcgcttt cttcctacgg tattttgcag  6840 agggtaatct tagaaaaggt gtttcacagt cttgtggcat gagtaacgag tccctgacgg  6900 ctgctctagc ttgcaagttg tcgcaggctg accttgactt tttgtccagc ttaacgaact  6960 tcaagtgctt tgtatctgct tcaaacatga aaaatgctgc cggccagtat attgaagcag  7020 cgtatgccaa ggccctgcgc caagagttgg cctccctagt tcaggttgac aaaatgaaag  7080 gaattttgtc taagcttgag gcctttgctg aaacagccac tccgtccctt gacgcaggtg  7140 acgtggttgt tctgcttggg caacatcctc acggatccat cctcgatatt aatgtgggga  7200 ctgaaaggaa aactgtgtcc gtgcaagaga cccggagctt aggtggttcc aaattcagtg  7260 tttgcactgt cgtgtccaac acacccgtgg acgccttaac tggcatccca ctccagacac  7320 caacccctct ttttgagaat ggtccgcgtc accgtggtga ggaagacgat cttagagtcg  7380 agaggatgaa gaaacactgt gtgtccctcg gcttccacaa cattaatggc aaagtttact  7440 gcaaaatttg ggacaagtcc accggtgata ccttttatac cgatgattcc cggtacaccc  7500 aagaccttgc attccaggac aggtcagccg actacagaga cagggattat gagggtgtgc  7560 aaaccgcccc ccaacagggc tttgatccaa agtctgaaac ccctattggc actgtggtga  7620 tcggcggtat cacgtataac aggtacctga tcaaaggtaa ggaggtcttg gttcccaagc  7680 ctgacaacgt ccttgaagct gccaagctgt cccttgagca agctctcgct gggatgggcc  7740 aaacttgcga ccttacagct gccgaggtgg aaaagttgag gcgcatcatt agccagctcc  7800 aaggtttgac cactgaacag gctttaaact gttagccgcc agcggcttga cccgctgtgg  7860 ccgcggcggc ttagttgtaa ctgaaacagc ggtaaaaatc gtaaagtacc acagcagaac  7920 tttcacccta ggccctctgg acctgaaagt cacctccgag gctgaggtaa agaaatcaac  7980 tgagcagggc cacgctgttg tggcaaactt atgttctggt gtcatcttga tgagacctca  8040 cccaccgtcc cttgttgatg ttcttctgaa acccggactt gacacaaaac ccggcattca  8100 accagggcat ggggccggga atatgggcgt agacggctct acttgggatt ttgaaaccgc  8160 acccacaaag gcagaacttg agttgtccaa acaaataatt caagcatgtg aagttaggcg  8220 cggggacgcc ccgaacctcc aactccctta caagctctat cctgttagag gggatcctga  8280 gcggcatggg ggccgcctta tcaataccag gtttggagat ctatcttaca aaacccctca  8340 agacaccaag tccgcaatcc atgcggcttg ttgcctgcac cccaacgggg cccctgtgtc  8400 tgatggtaag tcaacactag gtaccaccct tcaacatggt ttcgaacttt atgtccccac  8460 tgtgccctat agtgtcatgg agtacctcga ttcacgccct gacacccctt tcatgtgcac  8520 taaacatggt acttccaagg ctgctgcaga agacctccaa aaatacgacc tatctactca  8580 aggatttgtc ctgcccgggg tcttacgcct tgtacgcaga ttcatctttg gccatattgg  8640 taaggcaccg ccattgttcc tcccgtcaac ctatcccgct aaaaattcta tggcagggat  8700 caatggccag aggttcccaa caaaggacgt ccagagcata cctgaaattg acgaaatgtg  8760 tgcccgcgcc gtcaaggaga attggcaaac tgtgacacct tgtaccctca agaaacagta  8820 ctgttccaag cccaaaacca ggaccatcct gggcaccaac aactttattg ccctggctca  8880 ccgatcggcg ctcagtggtg tcacccaggc attcatgaag aaggcttgga agtccccgat  8940 tgccttggga aaaaacaaat tcaaggagct gcattgcact gtcgccggca ggtgtcttga  9000 agccgacttg gcctcctgtg accgcagcac ccccgccatt gtgaggtggt tcgtcgccaa  9060 cctcctgtat gaacttgcag gatgtgaaga gtacttgcct agctatgtgc ttaactgctg  9120 ccatgacctt gtggcaacac aggatggtgc cttcacaaaa cgcggtggcc tgtcgtccgg  9180 ggaccccgtc accagtgtgt ctaacaccgt atattcactg ataatctatg cccagcacat  9240 ggtgttgtcg gccttaaaaa tgggtcatga aatcggtctc aagttcctcg aggaacagct  9300 caaattcgag gacctcctcg aaatccagcc tatgttggtc tattctgatg accttgtctt  9360 gtacgctgaa aggcccactt ttcctaatta tcactggtgg gtcgagcacc ttgacctaat  9420 gctgggtttc agaacggacc caaagaagac agtcataact gataaaccca gcttcctcgg  9480 ctgcagaatt gaggcggggc gacagctggt ccctaatcgc gaccgcatcc tggctgctct  9540 cgcatatcac atgaaggcgc agaacgcctc agagtattat gcgtctgctg ccgcaatcct  9600 gatggattca tgtgcttgca ttgatcatga ccctgagtgg tatgaggacc tcatctgcgg  9660 tatcgcccga tgcgcccgcc aggatggtta tagtttccca ggcccggcat ttttcatgtc  9720 catgtgggaa aagctgagaa gtcacaatga agggaagaaa tttcgacact gcggcatctg  9780 cgacgccaaa gccgaccatg catccgcctg tgggcttgat ttgtgtttgt tccactcaca  9840 ctttcatcaa cactgccccg tcactctgag ctgtggtcat catgccggtt caagggaatg  9900 ttcgcagtgt cagtcacctg ttggggctgg cagatctcct cctgatgccg tgctaaaaca  9960 aatcctgtac aaacctcctc gtacagtcat catgaaggtg ggtaacaaaa caacggccct 10020 cgatccgggg aggtaccagt cccgtcgagg tcttgttgca gtcaagaggg gtattgcagg 10080 caatgaagtt gatcttcctg atggggacta ccaagtagtg cctcttttac caacttgtaa 10140 agacataaac atggtaaagg tggcttgcaa tgtactactc agtaagttca tagtggggcc 10200 accaggttcc ggaaagacca cctggttact gagtcaagtc caggacgatg atgtcattta 10260 cacacccacc catcagacca tgtttgatat agtcagtgct ctcaaagttt gcaggtattc 10320 tattccagga gcctcaggac ttcctttccc accacctgcc aggtccgggc cgtgggttag 10380 gctcgtggcc agcgggcacg tccccggccg aacatcatac ctcgatgagg ctggatattg 10440 taatcatctg gacattctca gactgctttc caaaacaccc ctcgtgtgtt tgggtgacct 10500 tcaacaactt caccctgtcg gctttgactc ctactgttat gtgtttgatc agatgcctca 10560 aaagcaactg accactattt atagatttgg ccctaacatc tgcgcagcca tccagccttg 10620 ttacagggag aagcttgaat ctaaggctag gaacaccagg gtggtcttta ccacctggcc 10680 tgtggccttt ggtcaggtgc tgacaccata ccataaagat cgcatcggct ctgcgataac 10740 catagactca tcccaggggg ccactttcga cattgtgaca ttgcatctac catcaccaaa 10800 gtccctaaat aaatcccgag cacttgtagc catcactcgg gcaagacacg ggttgttcat 10860 ttatgaccct cacaaccagc tccaggagtt tttcaacctg atccctgagc gcactgattg 10920 caaccttgtg ttcagccgtg gggatgatct ggtagttctt agtgcggaca atgcagtcac 10980 aactgtagcg aaggccctag ggacaggtcc atctcgattt cgagtatcag acccgaggtg 11040 caagtctctc ttagctgctt gttcggccag tctggagggg agctgtatgc cactaccaca 11100 agtggcacat aacctggggt tttacttctc cccagacagt ccagcatttg cacctctgcc 11160 aaaggagtta gcgccacatt ggccagtggt tactcaccag aacaatcggg cgtggcccga 11220 tcgacttgtc gctagtatgc gcccaattga tgcccgctac agcaagccaa tggtcggtgc 11280 agggtatgtg gtcgggccgt ccacctttct tggtactcct ggtgtagtgt catactacct 11340 cacgctatac atcaggggtg agccccaggc cttgccagag acactcgttt caacaggacg 11400 catagccact gactgccggg agtatctcga cgcggctgag gaagaggcag caaaagaact 11460 cccccacgca ttcattggcg atgtcaaagg taccacggtc ggggggtgtc accacatcac 11520 atcaaaatac ctacccagga ccctgcctaa ggactctgtt gctgtagttg gagtaagctc 11580 gcccggcagg gctgctaaag ccatgtgcac tctcactgat gtgtatctcc ccgaactccg 11640 gccatacctg caacctgaga cggcgtcgaa atgctggaaa ctcaaattag acttcaggga 11700 cgtccgacta atggtctgga aaggagccac cgcctatttc cagttggaag gacttacatg 11760 gtcagcgctg cctgactatg ccaggtttat tcagcttccc aaggacgccg ttgtgtacat 11820 tgatccgtgt ataggaccgg caacagccaa ccgcaaggtc gtgcgaacca cagactggcg 11880 ggccgacctg gcagtgacac cgtatgatta cggtgcccag aacattttga caacagcctg 11940 gttcgaggac ctcgggccgc agtggaagat tttggggttg cagcccttca ggcgggcatt 12000 tggctttgaa aatactgagg attgggcaat ccttgcacgc cgtatgagtg acggcaaaga 12060 ctacactgac tacaactggg attgtgttcg agaacgccca cacgccatct acgggcgtgc 12120 tcgtgaccat acatatcatt ttgcccccgg cacggaattg caggtagagc tgggtaaacc 12180 ccggctgccg cctggacgag agccgtaaac ttggagtgat gcaatggggt cactgtggag 12240 taaaatcagc cagctgttcg tggatgcctt cactgagttt cttgtcagtg tggttgatat 12300 tgtcattttc cttgccatac tgtttgggtt caccgtcgca ggatggttat tggtctttct 12360 tctcagagtg gtttgctccg cgcttctccg ttcgcgctct gccattcact ctcccgaact 12420 atcgaaggtc ctatgaaagc ttgttgccca actgcaggcc ggatgtccca caatttgcat 12480 ttaagcaccc attgggtata ctttggcaca tgcgagtttc ccacctgatt gatgagatgg 12540 tctctcgccg catttaccag accatggaac attcaggtca agcggcctgg aaatatgtgg 12600 tcggtgaggc cactctcacg aagctatcaa agcttgatat agttactcat ttccaacatc 12660 tggccgcagt agaggcggat tcttgccgct ttctcagctc acgactcgtg atgctaaaaa 12720 atcttgccgt tggcaatgtg agcctacagt acaacaccac gttggatcgc gttgaactca 12780 ttttccccac gccaggtacg aggcccaagt tgaccgactt cagacaatgg ctcatcagtg 12840 tgcatgcttc cattttttcc tctgtggctt catctgttac cttgttcata gtgctttggc 12900 tgcgaattcc agctctacgc tatgtttttg gtttccattg gcccacggca acacatcatt 12960 cgagctgacc atcaattata ccatatgcat gccctgtctt accagtcaag cagctcgcca 13020 aaggctcgag cccggtcgta acatgtggtg cagaataggg catgataggt gtgaggagcg 13080 tgaccatgat gagttgttaa tgtccatccc gtccgggtac gacaacctca aacttgaggg 13140 atattatgct tggctggctt ttttgtcctt ttcctacgcg gcccaattcc atccggagct 13200 gttcgggata gggaatgtgt cgcgcgtctt cgtggacaag cgacaccagt ttatttgtgc 13260 cgagcatggt ggactcaatt caaccttatc taccgagcac aatatctccg cattatatgc 13320 ggtattatta caccaccaaa tagacggggg taattggttc catttggaat ggctgcggcc 13380 gcttttttcc tcctggttgg tgctcaacat atcatggttt ctgaggcgtt cgcctgtaag 13440 ccctgtttct cgacgcatct atcagatatt aagaccaaca cgaccgcggc tgccggtttc 13500 atggtccttc agaacatcaa ttgttcccgg cctcacgagg cctcagcaac gcaaggtcaa 13560 gttccctcca gaaagtcgtc ccaatgccgt gaagccgtcg gtgttcccca atacatcacg 13620 ataacggcca acgtgaccga cgaatcatat ttgtacaacg cggacttgct gatgctttct 13680 gcgtgccttt tctacgcctc ggaaatgagc gagaaaggct ttaaagttat ctttgggaat 13740 gtctctggcg ttgtttctgc ttgtgtcaat ttcacagatt atgtggccca tgtgacccaa 13800 catacccagc agcatcatct ggtgattaat cacatccggt tactgcactt cctgacacca 13860 tctgcaatga ggtgggctac aaccattgct tgtctgttcg ccattctctt ggcgatatga 13920 aatgttctca caaattgggg cattccttga ctccgcactc ttgcttctgg tggctttttt 13980 tgctgtgtac cggcttgtcc tggtcctttg ccgatggcaa cggcaacaac tcgacatacc 14040 aatacatata taatttgacg atatgcgagt tgaatgggac caattggctg tccggccatt 14100 ttgaatgggc agttgagacc tttgtgcttt acccggttgt cactcatatc ctctcactgg 14160 gttttctcac gacaagtcat ttttttgacg cgctcggtct cggcgctgta tccactgcag 14220 gatttgtcgg agggcggtat gtacttagca gcgtctacgg cgcttgtgct ttcgcagcgt 14280 tcgtatgctt cgtcatccgt gctgctaaaa attgcatggc ctgccgctat gcccgtaccc 14340 ggttcaccaa cttcattgtg gacgaccggg ggggagttca tagatggaag tctccaatag 14400 tggtagaaaa actgggcaaa gccgaaattg gcggcaacct tgtcaccatc aaacatgtcg 14460 tcctcgaagg ggttaaagct caacccttga cgagaacttc ggccgagcaa tgggaggcct 14520 agataatttt tgcaacgatc ctaccgccgc acaaaagatc gtgctagcct tcagcatcac 14580 atacacacct ataatgatat acgcccttaa ggtgtcacgc ggccgactcc tggggctgtt 14640 gcacatccta atatttctga actgttcctt tacattcgga tacatgacat atgtgcattt 14700 tcattctacc caccgtgtcg cacttaccct gggggctgtt gtcgcccttt tgtggggtgt 14760 ctacagcctc acagagtcat ggaagtttat cacttccaga tgcagattgt gttgcctcgg 14820 ccggcgatac attctggccc ctgcccatca cgtagaaagt gctgcaggtc tccattcaat 14880 ctcagcgtct ggtaaccgag catacgctgt gagaaagccc ggactaacat cagtgaacgg 14940 cactctagta ccaggacttc ggagcctcgt gctgggcggc aaacgagctg ttaaacgagg 15000 agtggttaac ctcgtcaagt atggccggta aaaatcagag ccagaagaaa aagaaaagta 15060 cggctccaat ggggaatggc cagccagtca atcaactgtg ccagttgctg ggtgcaatga 15120 taaagtccca gcgccagcaa cctaggggag gacaggctaa aaagaaaaag cctgagaagc 15180 cacattttcc cctggctgca gaagatgaca tccggcacca cctcacccaa actgaacgct 15240 ccctctgctt gcaatcgatc cagacggctt tcaatcaagg cgcaggaact gcgtcgcttt 15300 catccagcgg gaaggtcagt ttccaggttg agtttatgct gccggttgct catacagtgc 15360 gcctgattcg cgtgacttct acatccgcca gtcagggtgc aaattaattt gacagtcagg 15420 tgaatggccg cgattggcgt gtggcctctg agtcacctat tcaattaggg cgatcacatg 15480 ggggtcatac ttaatcaggc aggaaccatg tgaccgaaat t 15521

REFERENCES

-   1. Allende, R., Lewis, T. L., Lu, Z., Rock, D. L., Kutish, G. F.,     Ali, A., Doster, A. R. & Osorio, F. A. (1999). North American and     European porcine reproductive and respiratory syndrome viruses     differ in non-structural protein coding regions. J Gen Virol 80,     307-315. -   2 Babiuk, L., Lewis, J., Suradhat, S., Baca-Estrada, M.,     Foldvari, M. & Babiuk, S. (1999). Polynucleotide vaccines: potential     for inducing immunity in animals. J Biotechnol 73, 131-140. -   3. Babiuk, L. A. (1999). Broadening the approaches to developing     more effective vaccines. Vaccine 17, 1587-1595. -   4. Babiuk, L. A., Babiuk, S. L. & Baca-Estrada, M. E. (2002). Novel     vaccine strategies. Adv Virus Res 58, 29-80. -   5. Barrett, T., Parida, S., Mohapatra, M., Walsh, P., Das, S. &     Baron, M. D. (2003). Development of new generation rinderpest     vaccines. Dev Biol 114, 89-97. -   6. Bautista, E. M., S. M. Goyal, I. J. Soon, H. S. Joo, and J. E.     Collins. 1996. Structural polypeptides of the American (VR-2332)     strain of porcine reproductive and respiratory syndrome virus. Arch.     Virol. 141:1357-1365. -   7. Benfield, D. A., E. Nelson, J. E. Collins, L. Harris, S. M.     Goyal, D. Robison, W. T. Christianson, R. B. Morrison, D. Gorcyca,     and D. Chladek. 1992. Characterization of swine infertility and     respiratory syndrome (SIRS) virus (isolate ATCC VR-2332). J. Vet.     Diagn. Invest. 4:127-133. -   8. Bosch, J. C., Kaashoek, M. J., Kroese, A. H. & Van     Oirschot, J. T. (1996). An attenuated bovine herpesvirus 1 marker     vaccine induces a better protection than two inactivated marker     vaccines. Vet Microbiol 52, 223-234. -   9. Calvert, J. G., M. G. Sheppard, and S. K. W. Welch. 2003.     Infectious cDNA clone of North American porcine reproductive and     respiratory syndrome (PRRS) virus and use thereof. US Patent     Application 20030157689. -   10. Calvert, J. G., M. G. Sheppard, and S. K. W. Welch. 2002.     Infectious cDNA clone of North American porcine reproductive and     respiratory syndrome (PRRS) virus and use thereof. U.S. Pat. No.     6,500,662. -   11. Castillo-Olivares, J., Wiering a, R. T., Bakonyi, A. A. F., de     Vries, N. J., Poyner, D. & Rottier, P. J. M. (2003). Generation of a     candidate live marker vaccine for equine arteritis virus by deletion     of the major virus neutralization domain. J Virol 77, 8470-8480. -   12. Collins, J. E., D. A. Benfield, W. T. Christianson, L.     Harris, J. C. Hennings, D. P. Shaw, S. M. Goyal, D. Gorcyca, D.     Chladek, S. McCullough, R. B. Morrison, and H. S. Joo. 1992.     Isolation of swine infertility and respiratory syndrome virus     (Isolate ATCC VR-2332) in North America and experimental     reproduction of the disease in gnotobiotic pigs. J. Vet. Diag.     Invest. 4:117-126. -   13. den Boon, J. A., K. S. Faaberg, J. J. M. Meulenberg, A. L. M.     Wassenaar, P. G. W. Plagemann, A. E. Gorbelenya, and E. J.     Snijder. 1995. Processing and evolution of the N-Terminal region of     the arterivirus replicase ORF1a protein: identification of two     papainlike cysteine proteases. J. Virol. 69:4500-4505. -   14. de Lima, M., Pattnaik, A. K., Flores, E. F. & Osorio, F. A.     (2006). Mapping of B-cell linear epitopes on Nsp2 and structural     proteins of a North American strain of porcine reproductive and     respiratory syndrome virus. Virology 353, 410-421. -   15. Fang, Y., D.-Y. Kim, S. Ropp, P. Steen, J.     Christopher-Hennings, E. A. Nelson, and R. R. R. Rowland. 2004.     Heterogeneity in Nsp2 of European-like porcine reproductive and     respiratory syndrome viruses isolated in the United States. Virus     Res. 100:229-235. -   16. Fang, Y., Rowland, R. R. R., Roof, M., Lunney, J. K.,     Christopher-Hennings, J. & Nelson, E. A. (2006). A full-length cDNA     infectious clone of North American type 1 porcine reproductive and     respiratory syndrome virus: expression of green fluorescent protein     in the nsp2 region. J Virol 80, 11447-11455. -   17. Fang, Y., Schneider, P., Zhang, W. P., Faaberg, K.,     Nelson, E. A. & Rowland, R. R. R. (2007). Diversity and evolution of     a newly emerged North American Type 1 porcine arterivirus. Arch     Virol 152, 1009-1017. -   18. Ferrin, N. H., Fang, Y., Johnson, C. R., Murtaugh, M. P.,     Polson, D. D., Torremorell, M., et al. (2004). Validation of a     Blocking ELISA for the detection of antibodies against porcine     reproductive and respiratory syndrome virus. Clin Diagn Lab 1 mm 11,     503-514. -   19. Fitzgerald, D. J., Bronson, E. D. & Anderson, J. N. (1996).     Compositional similarities between the human immunodeficiency virus     and surface antigens of pathogens. AIDS Res Hum Retroviruses 12, 99. -   20. Floegel-Niesmann, G. (2003). Marker vaccines and companion     diagnostic tests for classical swine fever. Dev Biol 114, 185-191. -   21. Frias-Staheli, N., Glannakopoulos, N. V., Klkkert, M.,     Taylor, S. L., Bridgen, A., Paragas, J., Richt, J. A.,     Rowland, R. R. R., Schmaljohn, C. S., Lenschow, D. J., Snijder, E.     J., Garcia-Sastre, A. & Virgin, H. W. (2007). Ovarian tumor     domain-containing viral proteases evade ubiquitin- and     ISG15-dependent innate immune responses. Cell Host Microbe 2,     404-416. -   22. Gao, Z. Q., X. Guo, and H. C. Yang. 2004. Genomic     characterization of two Chinese isolates of porcine respiratory and     reproductive syndrome virus. Arch. Virol. 149:1341-1351. -   23. Garrity, R. R., Rimmelzwaan, G., Minassian, A., Tsai, W. P.,     Lin, G., de Jong, J., Goudsmit, J. & Nara, P. (1997). Refocusing     neutralizing antibody response by targeted dampening of an     immunodominant epitope. J Immunology 159, 279-289. -   24. Hall, B. F. & Joiner, K. A. (1991). Strategies of obligate     intracellular parasites for evading host defenses. Immunol Today 12,     A22. -   25. Hayashi, N., Welschof, M., Zewe, M., Braunagel, M., Dübel, S.,     Breitling, F. & Little, M. (1994). Simultaneous mutagenesis of     antibody CDR regions by overlap extension and PCR. Biotechniques 17,     310, 312, 314-315. -   26. Halbur, P. G., P. S. Paul, M. L. Frey, J. Landgraf, K. Eernisse,     X.-J. Meng, M. A. Lum, J. J. Andrews, and J. A. Rathje. 1995.     Comparison of the pathogenicity of two U.S. porcine reproductive and     respiratory syndrome virus isolates with that of the Lelystad virus.     Vet. Pathol. 32:648-660. -   27. Han, J., Liu, G., Wang, Y. & Faaberg, K. S. (2007).     Identification of nonessential regions of the nsp2 replicase protein     of porcine reproductive and respiratory syndrome virus strain     VR-2332 for replication in cell culture. J Virol 81, 9878-9890. -   28. Ho, S. N., H. D. Hunt, R. M. Horton, J. K. Pullen, and L. R.     Pease. 1989. Site-directed mutagenesis by overlap extension using     the polymerase chain reaction. Gene. 77:51-59. -   29. Hopp, T. P. & Woods, K. R. (1981). Prediction of protein     antigenic determinants from amino acid sequences. Proc Natl Acad Sci     78, 3824-3828. -   30. Jespersen, T., D. Mogens, and F. S. Pedersen. 1997. Efficient     non-PCR-mediated overlap extension of PCR fragments by exonuclease     “end polishing.” Biotechniques 23:48-52. -   31. Johnson, C. R., Yu, W. & Murtaugh, M. (2007). Cross-reactive     antibody responses to nsp1 and nsp2 of Porcine reproductive and     respiratory syndrome virus. J Gen Virol 88, 1184-1195. -   32. Keffaber, K. K. 1989. Reproductive failure of unknown etiology.     Am. Assoc. Swine Pract. Newsl. 1:1-9. -   33. Kim, D. Y., Calvert, J. G., Chang, K. O., Horlen, K., Kerrigan,     M., Rowland, R. R. R. (2007). Expression and stability of foreign     tags inserted into nsp2 of porcine reproductive and respiratory     syndrome virus (PRRSV). Virus Research 128, 106-114. -   34. King, N. J. & Kesson, A. M. (2003). Interaction of flaviviruses     with cells of the vertebrate host and decoy of the immune response.     Immunol Cell Biol 81, 207-216. -   35. Konig, P., Beer, M., Makoschey, B., Teifke, J. P., Polster, U.,     Giesow, K. & Keil, G. M. (2003). Recombinant virus-expressed bovine     cytokines do not improve efficacy of a bovine herpesvirus 1 marker     vaccine strain. Vaccine 22, 202-212. -   36. Mardassi, H., B. Massive, and S. Dea. 1996. Intracellular     synthesis, processing, and transport of proteins encoded by ORFs 5     to 7 of porcine reproductive and respiratory syndrome virus.     Virology 221:98-112. -   37. Marrack, P. & Kappler, J. (1994). Subversion of the immune     system by pathogens. Cell 76, 323. -   38. Mebatsion, T., Koolen, M. J. M., de Vaan, L. T. C., de Haas, N.,     Braber, M., Romer-Oberdorfer, A., van den Elzen, P. & van der     Marel, P. (2002). Newcastle disease virus marker vaccine: an     immunodominant epitope on the nucleoprotein gene of NDV can be     deleted or replaced by a foreign epitope. J Virol 76, 10138-10146. -   39. Meng, X. J., P. S. Paul, I. Morozov, and P. G. Halbur. 1996. A     nested set of six or seven subgenomic mRNAs is formed in cells     infected with different isolates of porcine reproductive and     respiratory syndrome virus. J. Gen. Virol. 77:1265-1270. -   40. Meulenberg, J. J., J. N. Bos-de Ruijter, R. Van de Graaf, G.     Wensvoort, and M. Moormann. 1998. Infectious transcripts from cloned     genomic-length cDNA of porcine reproductive and respiratory syndrome     virus. J. Virol. 72:380-387. -   41. Meulenberg, J. J., and A. Petersen-den Besten. 1996.     Identification and characterization of a sixth structural protein of     Lelystad virus: the glycoprotein GP2 encoded by ORF2 is incorporated     in virus particles. Virology 225:44-51. -   42. Meulenberg, J. J. M., A. Petersen-den Besten, E. P. de     Kluyver, R. J. M. Moormann, W. M. M. Schaaper, and G.     Wensvoort. 1995. Characterization of proteins encoded by ORFs 2 to 7     of Lelystad virus. Virology 206:155-163. -   43. Meulenberg, J. J., M. M. Hulst, E. J. de Meijer, P. L.     Moonen, A. den Besten, E. P. de Kluyver, G. Wensvoort, and R. J.     Moormann. 1993. Lelystad virus, the causative agent of porcine     epidemic abortion and respiratory syndrome (PEARS), is related to     LDV and EAV. Virology 192:62-72. -   44. Moradpour, D., M. J. Evans, R. Gosert, Z. Yuan, H. E.     Blum, S. P. Goff, B. D. Lindenbach, and C. M. Rice. 2004. Insertion     of green fluorescent protein into nonstructural protein 5A allows     direct visualization of functional hepatitis C virus replication     complexes. J. Virol. 78:7400-7409. -   45. Mounir, S., H. Mardassi, and S. Dea. 1995. Identification and     characterization of the porcine reproductive respiratory virus ORFs     7, 5 and 4 products. Adv. Exp. Med. Biol. 80:317-320. -   46. Nara, P. L., Smit, L., Dunlop, N., Natch, W., Merges, M.,     Waters, D., Kelliher, J., Gallo, R. C., Fischinger, P. J. &     Goudsmit, J. (1990). Emergence of viruses resistant to     neutralization by V3-specific antibodies in experimental human     immunodeficiency virus type 1 IIIB infection of chimpanzees. J Virol     64, 3779-3791. -   47. Nelson, E. A., J. Christopher-Hennings, T. Drew, G.     Wensvoort, J. Collins, and D. A. Benfield. 1993. Differentiation of     U.S. and European isolates of porcine reproductive and respiratory     syndrome virus by monoclonal antibodies. J. Clin. Microbiol.     31:3184-3189. -   48. Nelson, E. A., J. Christopher-Hennings, and D. A.     Benfield. 1995. Structural proteins of porcine reproductive and     respiratory syndrome virus (PRRSV). Adv. Exp. Med. Biol.     380:321-323. -   49. Nelsen, C. J., Murtaugh, M. P. & Faaberg, K. S. (1999). Porcine     reproductive and respiratory syndrome virus comparison: divergent     evolution on two continents. J Virol 73, 270-280. -   50. Neumann, E. 2005. Assessment of the economic impact of porcine     reproductive and respiratory syndrome on swine production in the     United States. JAVMA, 227:385-392. -   51. Nielsen, H. S., G.-P. Liu, J. Nielsen, M. B. Oleksiewicz, A.     Botner, T. Storgaard, and K. S. Faaberg. 2003. Generation of an     infectious clone of VR-2332, a highly virulent North American-type     isolate of porcine reproductive and respiratory syndrome virus. J.     Virol. 77:3702-3711. -   52. Oleksiewicz, M. B., A. Botner, P. Toft, P. Normann, and T.     Storgaard. 2001. Epitope mapping porcine reproductive and     respiratory syndrome virus by phage display: the nsp2 fragment of     the replicase polyprotein contains a cluster of B-cell epitopes. J.     Virol. 75:3277-3290. -   53. Ropp, S. L., C. E. Mahlum Wees, Y. Fang, E. A. Nelson, K. D.     Rossow, M. Bien, B. Arndt, S. Preszler, P. Steen, J.     Christopher-Hennings, J. E. Collins, D. A. Benfield, and K. S.     Faaberg. 2004. Characterization of emerging European-like PRRSV     isolates in the United States. J. Virol. 78:3684-3703. -   54. Shen, S., J. Kwang, W. Liu, and D. X. Lui. 2000. Determination     of the complete nucleotide sequence of a vaccine strain of porcine     reproductive and respiratory syndrome virus and identification of     the nsp2 gene with a unique insertion. Arch. Virol. 145:871-883. -   55. Snijder, E. J., and J. J. Meulenberg. 1998. The molecular     biology of arteriviruses. J. Gen. Virol. 79:961-979. -   56. Snijder, E. J., A. L. M. Wassenaar, and W. J. M. Spaan. 1994.     Proteolytic processing of the replicase ORF1a protein of equine     arteritis virus. J. Virol. 68:5755-5764. -   57. Snijder, E. J., Wassenaar, A. L. M., Spaan, W. J. &     Gorbalenya, A. E. (1995). The arterivirus Nsp2 protease. An unusual     cysteine protease with primary structure similarities to both     papain-like and chymotrypsin-like proteases. J Biol Chem 270,     16671-16676. -   58. Sun, T., Lu, P. & Wang, X. (2004). Localization of     infection-related epitopes on the non-structural protein 3ABC of     foot-and-mouth disease virus and the application of tandem epitopes.     J Virol Methods 119, 79-86. -   59. Tian, K., Yu, X., Zhao, T., Feng, Y., Cao, Z., Wang, C., et al.     (2007). Emergence of fatal PRRSV variants: unparalleled outbreaks of     atypical PRRS in China and molecular dissection of the unique     hallmark. PLoS ONE 2, 526. -   60. Truong H. M., Z. Lu, G. Kutish, J. Galeota, F. A. Osorio,     and A. K. Pattnaik. 2004. A highly pathogenic porcine reproductive     and respiratory syndrome virus generated from an infectious cDNA     clone retains the in vivo markers of virulence and transmissibility     characteristics of the parental strain. Virology. 325:308-319. -   61. van Dinten, L. C., A. L. Wassenaar, A. E. Gorbalenya, W. J.     Spaan, and E. J. Snijder. 1996. Processing of the equine arteritis     virus replicase ORF1b protein: identification of cleavage products     containing the putative viral polymerase and helicase domains. J.     Virol. 70:6625-6633. -   62. van Gennip, H. G., Bouma, A., van Rijn, P. A.,     Widjojoatmodjo M. N. & Moormann, R. J. (2002). Experimental     non-transmissible marker vaccines for classical swine fever (CSF) by     trans-complementation of E(rns) or E2 of CSFV. Vaccine 20,     1544-1556. -   63. van Oirschot, J. T. (2001). Present a future of veterinary viral     vaccinology: a review. Vet. Quart 23, 100-108. -   64. van Oirschot, J. T., Kaashoek, M. J., Rijsewijk, F. A. &     Stegeman, J. A. (1996). The use of marker vaccines in eradication of     herpesviruses. J Biotechnol 44, 75-81. -   65. Vijayakrishanan, L., Kumar, V., Agrewala, J. N., Mishra, G. C. &     Rao, K. V. (1994). Antigen-specific early primary humoral responses     modulate immunodominance of B cell epitopes. J Immunol. 153,     1613-1625. -   66. Walsh, E. P., Baron, M. D., Rennie, L., Anderson, J. &     Barrett, T. (2000). Development of a genetically marked recombinant     rinderpest vaccine expressing green fluorescent protein. J Gen Virol     81, 709-718. -   67. Wasilk, A., J. Callahan, J. Christopher-Hennings, B. T. Gay, Y.     Fang, M. Dammen, M. Torremorell, D. Polson, M. Mellencamp, E. A.     Nelson and W. Nelson. 2004. Detection of U.S. and     Lelystad/European-like porcine reproductive and respiratory syndrome     virus and relative quantitation in boar semen and serum by real-time     PCR. J. Clin. Micro. 42:4453-4461. -   68. Wassenaar, A. L., W. J. Spaan, A. E. Gorbalenya, and E. J.     Snijder. 1997. Alternative proteolytic processing of the arterivirus     replicase ORF1a polyprotein: evidence that Nsp2 acts as a cofactor     for the Nsp4 serine protease. J. Virol. 71:9313-9322. -   69. Wensvoort, G., C. Terpstra, J. M. Pol., E. A. ter Laak, M.     Bloemrad, E. P. deKluyer, C. Kragten, L. van Buiten, A. den     Besten, F. Wagenaar, J. M. Broekhuijsen, P. L. J. M. Moonen, T.     Zetstra, E. A. de Boer, H. J. Tibben, M. F. de Jong, P. van't     Veld, G. J. R. Groenland, J. A. van Gennep, M. T. H. Voets, J. H. M.     Verheijden, and J. Braamskamp. 1991. Mystery swine disease in the     Netherlands: the isolation of Lelystad virus. Vet. Quarterly     13:121-130. -   70. Widjojoatmodjo, M. N., van Gennip, H. G., Bouma, A., van     Rijn, P. A., Moormann, R. J. (2000). Classical swine fever virus     E(rns) deletion mutants: trans-complementation and potential use as     non transmissible, modified, live-attenuated marker vaccines. J     Virol 74, 2973-2980. -   71. Wu, W. H., Fang, Y., Rowland, R. R. R., Lawson, S. R.,     Christopher-Hennings, J., Yoon, K. J. & Nelson, E. A. (2005). The 2b     protein as a minor structural component of PRRSV. Virus Res 114,     177-181. -   72. Wu, W. H., Y. Fang, R. Farwell, M. Steffen-Bien, R. R.     Rowland, J. Christopher-Hennings, and E. A. Nelson. 2001. A 10-kDa     structural protein of porcine reproductive and respiratory syndrome     virus encoded by ORF 2b. Virology 287:183-191. -   73. Zeman, D., R. Neiger, M. Yaeger, E. Nelson, D. Benfield, P.     Leslie-Steen, J. Thomson, D. Miskimins, R. Daly, and M.     Minehart. 1993. Laboratory investigation of PRRS virus infection in     three swine herds. J. Vet. Diagn. Invest. 5:522-528. -   74. Y. Fang, B. Neiger, T. Hawkins, J. Christopher-Hennings, R.     Rowland, E. Nelson, Proc. Conf. Res. Work. Anim. Dis., abstr. 78,     2004 

1. A method comprising differentiating a subject previously vaccinated against North American Type 1 PRRSV with a marker vaccine from a subject previously naturally infected with PRRSV, the method comprising: collecting a sample from a subject, determining a presence of amino acids 736-790 of ORF1a in non-structural protein 2 of North American Type 1 PRRSV in the sample via immunological assay; and determining a presence of a GFP marker inserted between amino acids 733 and 734 of ORF1a in non-structural protein 2 of North American Type 1 PRRSV in the sample via immunological assay, wherein the presence of the GFP marker in the sample and an absence of the amino acids 736-790 of ORF1a in non-structural protein 2 of a North American Type 1 PRRSV in the sample is indicative of a subject previously vaccinated against North American Type 1 PRRSV.
 2. The method of claim 1, wherein the presence of a amino acids 736-790 of ORF1a in non-structural protein 2 of a North American Type 1 PRRSV is determined by incubating the sample with an antibody against the wild-type epitope of a North American Type 1 PRRSV.
 3. The method of claim 1 wherein the marker vaccine comprises SEQ ID NO:
 43. 